/*
 * Copyright (C) 2012 The Android Open Source Project
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

#include <math.h>
#include <string.h>

#include "arch/arm/asm_support_arm.h"
#include "base/bit_utils.h"
#include "entrypoints/entrypoint_utils.h"
#include "entrypoints/jni/jni_entrypoints.h"
#include "entrypoints/math_entrypoints.h"
#include "entrypoints/quick/quick_alloc_entrypoints.h"
#include "entrypoints/quick/quick_default_externs.h"
#include "entrypoints/quick/quick_default_init_entrypoints.h"
#include "entrypoints/quick/quick_entrypoints.h"
#include "entrypoints/runtime_asm_entrypoints.h"
#include "interpreter/interpreter.h"

namespace art {

// Cast entrypoints.
extern "C" size_t artInstanceOfFromCode(mirror::Object* obj, mirror::Class* ref_class);

// Read barrier entrypoints.
// art_quick_read_barrier_mark_regX uses an non-standard calling
// convention: it expects its input in register X and returns its
// result in that same register, and saves and restores all
// caller-save registers.
extern "C" mirror::Object* art_quick_read_barrier_mark_reg00(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg01(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg02(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg03(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg04(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg05(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg06(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg07(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg08(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg09(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg10(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg11(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_reg12(mirror::Object*);

extern "C" mirror::Object* art_quick_read_barrier_mark_introspection(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_introspection_narrow(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_introspection_arrays(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_introspection_gc_roots_wide(mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_introspection_gc_roots_narrow(
    mirror::Object*);
extern "C" mirror::Object* art_quick_read_barrier_mark_introspection_unsafe_cas(mirror::Object*);

// Used by soft float.
// Single-precision FP arithmetics.
extern "C" float fmodf(float a, float b);              // REM_FLOAT[_2ADDR]
// Double-precision FP arithmetics.
extern "C" double fmod(double a, double b);            // REM_DOUBLE[_2ADDR]

// Used by hard float.
extern "C" float art_quick_fmodf(float a, float b);    // REM_FLOAT[_2ADDR]
extern "C" double art_quick_fmod(double a, double b);  // REM_DOUBLE[_2ADDR]

// Integer arithmetics.
extern "C" int __aeabi_idivmod(int32_t, int32_t);  // [DIV|REM]_INT[_2ADDR|_LIT8|_LIT16]

// Long long arithmetics - REM_LONG[_2ADDR] and DIV_LONG[_2ADDR]
extern "C" int64_t __aeabi_ldivmod(int64_t, int64_t);

void UpdateReadBarrierEntrypoints(QuickEntryPoints* qpoints, bool is_active) {
  qpoints->pReadBarrierMarkReg00 = is_active ? art_quick_read_barrier_mark_reg00 : nullptr;
  qpoints->pReadBarrierMarkReg01 = is_active ? art_quick_read_barrier_mark_reg01 : nullptr;
  qpoints->pReadBarrierMarkReg02 = is_active ? art_quick_read_barrier_mark_reg02 : nullptr;
  qpoints->pReadBarrierMarkReg03 = is_active ? art_quick_read_barrier_mark_reg03 : nullptr;
  qpoints->pReadBarrierMarkReg04 = is_active ? art_quick_read_barrier_mark_reg04 : nullptr;
  qpoints->pReadBarrierMarkReg05 = is_active ? art_quick_read_barrier_mark_reg05 : nullptr;
  qpoints->pReadBarrierMarkReg06 = is_active ? art_quick_read_barrier_mark_reg06 : nullptr;
  qpoints->pReadBarrierMarkReg07 = is_active ? art_quick_read_barrier_mark_reg07 : nullptr;
  qpoints->pReadBarrierMarkReg08 = is_active ? art_quick_read_barrier_mark_reg08 : nullptr;
  qpoints->pReadBarrierMarkReg09 = is_active ? art_quick_read_barrier_mark_reg09 : nullptr;
  qpoints->pReadBarrierMarkReg10 = is_active ? art_quick_read_barrier_mark_reg10 : nullptr;
  qpoints->pReadBarrierMarkReg11 = is_active ? art_quick_read_barrier_mark_reg11 : nullptr;

  if (kUseReadBarrier && kUseBakerReadBarrier) {
    // For the alignment check, strip the Thumb mode bit.
    DCHECK_ALIGNED(reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection) - 1u,
                   256u);
    // Check the field narrow entrypoint offset from the introspection entrypoint.
    intptr_t narrow_diff =
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection_narrow) -
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection);
    DCHECK_EQ(BAKER_MARK_INTROSPECTION_FIELD_LDR_NARROW_ENTRYPOINT_OFFSET, narrow_diff);
    // Check array switch cases offsets from the introspection entrypoint.
    intptr_t array_diff =
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection_arrays) -
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection);
    DCHECK_EQ(BAKER_MARK_INTROSPECTION_ARRAY_SWITCH_OFFSET, array_diff);
    // Check the GC root entrypoint offsets from the introspection entrypoint.
    intptr_t gc_roots_wide_diff =
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection_gc_roots_wide) -
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection);
    DCHECK_EQ(BAKER_MARK_INTROSPECTION_GC_ROOT_LDR_WIDE_ENTRYPOINT_OFFSET, gc_roots_wide_diff);
    intptr_t gc_roots_narrow_diff =
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection_gc_roots_narrow) -
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection);
    DCHECK_EQ(BAKER_MARK_INTROSPECTION_GC_ROOT_LDR_NARROW_ENTRYPOINT_OFFSET, gc_roots_narrow_diff);
    intptr_t unsafe_cas_diff =
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection_unsafe_cas) -
        reinterpret_cast<intptr_t>(art_quick_read_barrier_mark_introspection);
    DCHECK_EQ(BAKER_MARK_INTROSPECTION_UNSAFE_CAS_ENTRYPOINT_OFFSET, unsafe_cas_diff);
    // The register 12, i.e. IP, is reserved, so there is no art_quick_read_barrier_mark_reg12.
    // We're using the entry to hold a pointer to the introspection entrypoint instead.
    qpoints->pReadBarrierMarkReg12 =
        is_active ? art_quick_read_barrier_mark_introspection : nullptr;
  }
}

void InitEntryPoints(JniEntryPoints* jpoints, QuickEntryPoints* qpoints) {
  DefaultInitEntryPoints(jpoints, qpoints);

  // Cast
  qpoints->pInstanceofNonTrivial = artInstanceOfFromCode;
  qpoints->pCheckInstanceOf = art_quick_check_instance_of;

  // Math
  qpoints->pIdivmod = __aeabi_idivmod;
  qpoints->pLdiv = __aeabi_ldivmod;
  qpoints->pLmod = __aeabi_ldivmod;  // result returned in r2:r3
  qpoints->pLmul = art_quick_mul_long;
  qpoints->pShlLong = art_quick_shl_long;
  qpoints->pShrLong = art_quick_shr_long;
  qpoints->pUshrLong = art_quick_ushr_long;
  qpoints->pFmod = art_quick_fmod;
  qpoints->pFmodf = art_quick_fmodf;
  qpoints->pD2l = art_quick_d2l;
  qpoints->pF2l = art_quick_f2l;
  qpoints->pL2f = art_quick_l2f;

  // More math.
  qpoints->pCos = cos;
  qpoints->pSin = sin;
  qpoints->pAcos = acos;
  qpoints->pAsin = asin;
  qpoints->pAtan = atan;
  qpoints->pAtan2 = atan2;
  qpoints->pPow = pow;
  qpoints->pCbrt = cbrt;
  qpoints->pCosh = cosh;
  qpoints->pExp = exp;
  qpoints->pExpm1 = expm1;
  qpoints->pHypot = hypot;
  qpoints->pLog = log;
  qpoints->pLog10 = log10;
  qpoints->pNextAfter = nextafter;
  qpoints->pSinh = sinh;
  qpoints->pTan = tan;
  qpoints->pTanh = tanh;

  // Intrinsics
  qpoints->pIndexOf = art_quick_indexof;
  // The ARM StringCompareTo intrinsic does not call the runtime.
  qpoints->pStringCompareTo = nullptr;
  qpoints->pMemcpy = memcpy;

  // Read barrier.
  qpoints->pReadBarrierJni = ReadBarrierJni;
  UpdateReadBarrierEntrypoints(qpoints, /*is_active=*/ false);
  qpoints->pReadBarrierMarkReg12 = nullptr;  // Cannot use register 12 (IP) to pass arguments.
  qpoints->pReadBarrierMarkReg13 = nullptr;  // Cannot use register 13 (SP) to pass arguments.
  qpoints->pReadBarrierMarkReg14 = nullptr;  // Cannot use register 14 (LR) to pass arguments.
  qpoints->pReadBarrierMarkReg15 = nullptr;  // Cannot use register 15 (PC) to pass arguments.
  // ARM has only 16 core registers.
  qpoints->pReadBarrierMarkReg16 = nullptr;
  qpoints->pReadBarrierMarkReg17 = nullptr;
  qpoints->pReadBarrierMarkReg18 = nullptr;
  qpoints->pReadBarrierMarkReg19 = nullptr;
  qpoints->pReadBarrierMarkReg20 = nullptr;
  qpoints->pReadBarrierMarkReg21 = nullptr;
  qpoints->pReadBarrierMarkReg22 = nullptr;
  qpoints->pReadBarrierMarkReg23 = nullptr;
  qpoints->pReadBarrierMarkReg24 = nullptr;
  qpoints->pReadBarrierMarkReg25 = nullptr;
  qpoints->pReadBarrierMarkReg26 = nullptr;
  qpoints->pReadBarrierMarkReg27 = nullptr;
  qpoints->pReadBarrierMarkReg28 = nullptr;
  qpoints->pReadBarrierMarkReg29 = nullptr;
  qpoints->pReadBarrierSlow = artReadBarrierSlow;
  qpoints->pReadBarrierForRootSlow = artReadBarrierForRootSlow;
}

}  // namespace art