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gerrit-public.fairphone.software / fp2-dev / platform / external / v8 / da12d29b40bc9ac10bcdeb5696b69c3ed0d3133f / . / src / s390 / simulator-s390.h
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// Copyright 2014 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
// Declares a Simulator for S390 instructions if we are not generating a native
// S390 binary. This Simulator allows us to run and debug S390 code generation
// on regular desktop machines.
// V8 calls into generated code by "calling" the CALL_GENERATED_CODE macro,
// which will start execution in the Simulator or forwards to the real entry
// on a S390 hardware platform.
#ifndef V8_S390_SIMULATOR_S390_H_
#define V8_S390_SIMULATOR_S390_H_
#include "src/allocation.h"
#if !defined(USE_SIMULATOR)
// Running without a simulator on a native s390 platform.
namespace v8 {
namespace internal {
// When running without a simulator we call the entry directly.
#define CALL_GENERATED_CODE(isolate, entry, p0, p1, p2, p3, p4) \
(entry(p0, p1, p2, p3, p4))
typedef int (*s390_regexp_matcher)(String*, int, const byte*, const byte*, int*,
int, Address, int, void*, Isolate*);
// Call the generated regexp code directly. The code at the entry address
// should act as a function matching the type ppc_regexp_matcher.
// The ninth argument is a dummy that reserves the space used for
// the return address added by the ExitFrame in native calls.
#define CALL_GENERATED_REGEXP_CODE(isolate, entry, p0, p1, p2, p3, p4, p5, p6, \
p7, p8) \
(FUNCTION_CAST<s390_regexp_matcher>(entry)(p0, p1, p2, p3, p4, p5, p6, p7, \
NULL, p8))
// The stack limit beyond which we will throw stack overflow errors in
// generated code. Because generated code on s390 uses the C stack, we
// just use the C stack limit.
class SimulatorStack : public v8::internal::AllStatic {
public:
static inline uintptr_t JsLimitFromCLimit(v8::internal::Isolate* isolate,
uintptr_t c_limit) {
USE(isolate);
return c_limit;
}
static inline uintptr_t RegisterCTryCatch(v8::internal::Isolate* isolate,
uintptr_t try_catch_address) {
USE(isolate);
return try_catch_address;
}
static inline void UnregisterCTryCatch(v8::internal::Isolate* isolate) {
USE(isolate);
}
};
} // namespace internal
} // namespace v8
#else // !defined(USE_SIMULATOR)
// Running with a simulator.
#include "src/assembler.h"
#include "src/hashmap.h"
#include "src/s390/constants-s390.h"
namespace v8 {
namespace internal {
class CachePage {
public:
static const int LINE_VALID = 0;
static const int LINE_INVALID = 1;
static const int kPageShift = 12;
static const int kPageSize = 1 << kPageShift;
static const int kPageMask = kPageSize - 1;
static const int kLineShift = 2; // The cache line is only 4 bytes right now.
static const int kLineLength = 1 << kLineShift;
static const int kLineMask = kLineLength - 1;
CachePage() { memset(&validity_map_, LINE_INVALID, sizeof(validity_map_)); }
char* ValidityByte(int offset) {
return &validity_map_[offset >> kLineShift];
}
char* CachedData(int offset) { return &data_[offset]; }
private:
char data_[kPageSize]; // The cached data.
static const int kValidityMapSize = kPageSize >> kLineShift;
char validity_map_[kValidityMapSize]; // One byte per line.
};
class Simulator {
public:
friend class S390Debugger;
enum Register {
no_reg = -1,
r0 = 0,
r1 = 1,
r2 = 2,
r3 = 3,
r4 = 4,
r5 = 5,
r6 = 6,
r7 = 7,
r8 = 8,
r9 = 9,
r10 = 10,
r11 = 11,
r12 = 12,
r13 = 13,
r14 = 14,
r15 = 15,
fp = r11,
ip = r12,
cp = r13,
ra = r14,
sp = r15, // name aliases
kNumGPRs = 16,
d0 = 0,
d1,
d2,
d3,
d4,
d5,
d6,
d7,
d8,
d9,
d10,
d11,
d12,
d13,
d14,
d15,
kNumFPRs = 16
};
explicit Simulator(Isolate* isolate);
~Simulator();
// The currently executing Simulator instance. Potentially there can be one
// for each native thread.
static Simulator* current(v8::internal::Isolate* isolate);
// Accessors for register state.
void set_register(int reg, uint64_t value);
uint64_t get_register(int reg) const;
template <typename T>
T get_low_register(int reg) const;
template <typename T>
T get_high_register(int reg) const;
void set_low_register(int reg, uint32_t value);
void set_high_register(int reg, uint32_t value);
double get_double_from_register_pair(int reg);
void set_d_register_from_double(int dreg, const double dbl) {
DCHECK(dreg >= 0 && dreg < kNumFPRs);
*bit_cast<double*>(&fp_registers_[dreg]) = dbl;
}
double get_double_from_d_register(int dreg) {
DCHECK(dreg >= 0 && dreg < kNumFPRs);
return *bit_cast<double*>(&fp_registers_[dreg]);
}
void set_d_register(int dreg, int64_t value) {
DCHECK(dreg >= 0 && dreg < kNumFPRs);
fp_registers_[dreg] = value;
}
int64_t get_d_register(int dreg) {
DCHECK(dreg >= 0 && dreg < kNumFPRs);
return fp_registers_[dreg];
}
void set_d_register_from_float32(int dreg, const float f) {
DCHECK(dreg >= 0 && dreg < kNumFPRs);
int32_t f_int = *bit_cast<int32_t*>(&f);
int64_t finalval = static_cast<int64_t>(f_int) << 32;
set_d_register(dreg, finalval);
}
float get_float32_from_d_register(int dreg) {
DCHECK(dreg >= 0 && dreg < kNumFPRs);
int64_t regval = get_d_register(dreg) >> 32;
int32_t regval32 = static_cast<int32_t>(regval);
return *bit_cast<float*>(&regval32);
}
// Special case of set_register and get_register to access the raw PC value.
void set_pc(intptr_t value);
intptr_t get_pc() const;
Address get_sp() const {
return reinterpret_cast<Address>(static_cast<intptr_t>(get_register(sp)));
}
// Accessor to the internal simulator stack area.
uintptr_t StackLimit(uintptr_t c_limit) const;
// Executes S390 instructions until the PC reaches end_sim_pc.
void Execute();
// Call on program start.
static void Initialize(Isolate* isolate);
static void TearDown(HashMap* i_cache, Redirection* first);
// V8 generally calls into generated JS code with 5 parameters and into
// generated RegExp code with 7 parameters. This is a convenience function,
// which sets up the simulator state and grabs the result on return.
intptr_t Call(byte* entry, int argument_count, ...);
// Alternative: call a 2-argument double function.
void CallFP(byte* entry, double d0, double d1);
int32_t CallFPReturnsInt(byte* entry, double d0, double d1);
double CallFPReturnsDouble(byte* entry, double d0, double d1);
// Push an address onto the JS stack.
uintptr_t PushAddress(uintptr_t address);
// Pop an address from the JS stack.
uintptr_t PopAddress();
// Debugger input.
void set_last_debugger_input(char* input);
char* last_debugger_input() { return last_debugger_input_; }
// ICache checking.
static void FlushICache(v8::internal::HashMap* i_cache, void* start,
size_t size);
// Returns true if pc register contains one of the 'special_values' defined
// below (bad_lr, end_sim_pc).
bool has_bad_pc() const;
private:
enum special_values {
// Known bad pc value to ensure that the simulator does not execute
// without being properly setup.
bad_lr = -1,
// A pc value used to signal the simulator to stop execution. Generally
// the lr is set to this value on transition from native C code to
// simulated execution, so that the simulator can "return" to the native
// C code.
end_sim_pc = -2
};
// Unsupported instructions use Format to print an error and stop execution.
void Format(Instruction* instr, const char* format);
// Helper functions to set the conditional flags in the architecture state.
bool CarryFrom(int32_t left, int32_t right, int32_t carry = 0);
bool BorrowFrom(int32_t left, int32_t right);
template <typename T1>
inline bool OverflowFromSigned(T1 alu_out, T1 left, T1 right, bool addition);
// Helper functions to decode common "addressing" modes
int32_t GetShiftRm(Instruction* instr, bool* carry_out);
int32_t GetImm(Instruction* instr, bool* carry_out);
void ProcessPUW(Instruction* instr, int num_regs, int operand_size,
intptr_t* start_address, intptr_t* end_address);
void HandleRList(Instruction* instr, bool load);
void HandleVList(Instruction* inst);
void SoftwareInterrupt(Instruction* instr);
// Stop helper functions.
inline bool isStopInstruction(Instruction* instr);
inline bool isWatchedStop(uint32_t bkpt_code);
inline bool isEnabledStop(uint32_t bkpt_code);
inline void EnableStop(uint32_t bkpt_code);
inline void DisableStop(uint32_t bkpt_code);
inline void IncreaseStopCounter(uint32_t bkpt_code);
void PrintStopInfo(uint32_t code);
// Byte Reverse
inline int16_t ByteReverse(int16_t hword);
inline int32_t ByteReverse(int32_t word);
// Read and write memory.
inline uint8_t ReadBU(intptr_t addr);
inline int8_t ReadB(intptr_t addr);
inline void WriteB(intptr_t addr, uint8_t value);
inline void WriteB(intptr_t addr, int8_t value);
inline uint16_t ReadHU(intptr_t addr, Instruction* instr);
inline int16_t ReadH(intptr_t addr, Instruction* instr);
// Note: Overloaded on the sign of the value.
inline void WriteH(intptr_t addr, uint16_t value, Instruction* instr);
inline void WriteH(intptr_t addr, int16_t value, Instruction* instr);
inline uint32_t ReadWU(intptr_t addr, Instruction* instr);
inline int32_t ReadW(intptr_t addr, Instruction* instr);
inline void WriteW(intptr_t addr, uint32_t value, Instruction* instr);
inline void WriteW(intptr_t addr, int32_t value, Instruction* instr);
inline int64_t ReadDW(intptr_t addr);
inline double ReadDouble(intptr_t addr);
inline void WriteDW(intptr_t addr, int64_t value);
// S390
void Trace(Instruction* instr);
bool DecodeTwoByte(Instruction* instr);
bool DecodeFourByte(Instruction* instr);
bool DecodeFourByteArithmetic(Instruction* instr);
bool DecodeFourByteArithmetic64Bit(Instruction* instr);
bool DecodeFourByteFloatingPoint(Instruction* instr);
void DecodeFourByteFloatingPointIntConversion(Instruction* instr);
void DecodeFourByteFloatingPointRound(Instruction* instr);
bool DecodeSixByte(Instruction* instr);
bool DecodeSixByteArithmetic(Instruction* instr);
bool S390InstructionDecode(Instruction* instr);
void DecodeSixByteBitShift(Instruction* instr);
// Used by the CL**BR instructions.
template <typename T1, typename T2>
void SetS390RoundConditionCode(T1 r2_val, T2 max, T2 min) {
condition_reg_ = 0;
double r2_dval = static_cast<double>(r2_val);
double dbl_min = static_cast<double>(min);
double dbl_max = static_cast<double>(max);
if (r2_dval == 0.0)
condition_reg_ = 8;
else if (r2_dval < 0.0 && r2_dval >= dbl_min && std::isfinite(r2_dval))
condition_reg_ = 4;
else if (r2_dval > 0.0 && r2_dval <= dbl_max && std::isfinite(r2_dval))
condition_reg_ = 2;
else
condition_reg_ = 1;
}
template <typename T1>
void SetS390RoundConditionCode(T1 r2_val, int64_t max, int64_t min) {
condition_reg_ = 0;
double r2_dval = static_cast<double>(r2_val);
double dbl_min = static_cast<double>(min);
double dbl_max = static_cast<double>(max);
// Note that the IEEE 754 floating-point representations (both 32 and
// 64 bit) cannot exactly represent INT64_MAX. The closest it can get
// is INT64_max + 1. IEEE 754 FP can, though, represent INT64_MIN
// exactly.
// This is not an issue for INT32, as IEEE754 64-bit can represent
// INT32_MAX and INT32_MIN with exact precision.
if (r2_dval == 0.0)
condition_reg_ = 8;
else if (r2_dval < 0.0 && r2_dval >= dbl_min && std::isfinite(r2_dval))
condition_reg_ = 4;
else if (r2_dval > 0.0 && r2_dval < dbl_max && std::isfinite(r2_dval))
condition_reg_ = 2;
else
condition_reg_ = 1;
}
// Used by the CL**BR instructions.
template <typename T1, typename T2, typename T3>
void SetS390ConvertConditionCode(T1 src, T2 dst, T3 max) {
condition_reg_ = 0;
if (src == static_cast<T1>(0.0)) {
condition_reg_ |= 8;
} else if (src < static_cast<T1>(0.0) && static_cast<T2>(src) == 0 &&
std::isfinite(src)) {
condition_reg_ |= 4;
} else if (src > static_cast<T1>(0.0) && std::isfinite(src) &&
src < static_cast<T1>(max)) {
condition_reg_ |= 2;
} else {
condition_reg_ |= 1;
}
}
template <typename T>
void SetS390ConditionCode(T lhs, T rhs) {
condition_reg_ = 0;
if (lhs == rhs) {
condition_reg_ |= CC_EQ;
} else if (lhs < rhs) {
condition_reg_ |= CC_LT;
} else if (lhs > rhs) {
condition_reg_ |= CC_GT;
}
// We get down here only for floating point
// comparisons and the values are unordered
// i.e. NaN
if (condition_reg_ == 0) condition_reg_ = unordered;
}
// Used by arithmetic operations that use carry.
template <typename T>
void SetS390ConditionCodeCarry(T result, bool overflow) {
condition_reg_ = 0;
bool zero_result = (result == static_cast<T>(0));
if (zero_result && !overflow) {
condition_reg_ |= 8;
} else if (!zero_result && !overflow) {
condition_reg_ |= 4;
} else if (zero_result && overflow) {
condition_reg_ |= 2;
} else if (!zero_result && overflow) {
condition_reg_ |= 1;
}
if (condition_reg_ == 0) UNREACHABLE();
}
bool isNaN(double value) { return (value != value); }
// Set the condition code for bitwise operations
// CC0 is set if value == 0.
// CC1 is set if value != 0.
// CC2/CC3 are not set.
template <typename T>
void SetS390BitWiseConditionCode(T value) {
condition_reg_ = 0;
if (value == 0)
condition_reg_ |= CC_EQ;
else
condition_reg_ |= CC_LT;
}
void SetS390OverflowCode(bool isOF) {
if (isOF) condition_reg_ = CC_OF;
}
bool TestConditionCode(Condition mask) {
// Check for unconditional branch
if (mask == 0xf) return true;
return (condition_reg_ & mask) != 0;
}
// Executes one instruction.
void ExecuteInstruction(Instruction* instr, bool auto_incr_pc = true);
// ICache.
static void CheckICache(v8::internal::HashMap* i_cache, Instruction* instr);
static void FlushOnePage(v8::internal::HashMap* i_cache, intptr_t start,
int size);
static CachePage* GetCachePage(v8::internal::HashMap* i_cache, void* page);
// Runtime call support.
static void* RedirectExternalReference(
Isolate* isolate, void* external_function,
v8::internal::ExternalReference::Type type);
// Handle arguments and return value for runtime FP functions.
void GetFpArgs(double* x, double* y, intptr_t* z);
void SetFpResult(const double& result);
void TrashCallerSaveRegisters();
void CallInternal(byte* entry, int reg_arg_count = 3);
// Architecture state.
// On z9 and higher and supported Linux on z Systems platforms, all registers
// are 64-bit, even in 31-bit mode.
uint64_t registers_[kNumGPRs];
int64_t fp_registers_[kNumFPRs];
// Condition Code register. In S390, the last 4 bits are used.
int32_t condition_reg_;
// Special register to track PC.
intptr_t special_reg_pc_;
// Simulator support.
char* stack_;
static const size_t stack_protection_size_ = 256 * kPointerSize;
bool pc_modified_;
int64_t icount_;
// Debugger input.
char* last_debugger_input_;
// Icache simulation
v8::internal::HashMap* i_cache_;
// Registered breakpoints.
Instruction* break_pc_;
Instr break_instr_;
v8::internal::Isolate* isolate_;
// A stop is watched if its code is less than kNumOfWatchedStops.
// Only watched stops support enabling/disabling and the counter feature.
static const uint32_t kNumOfWatchedStops = 256;
// Breakpoint is disabled if bit 31 is set.
static const uint32_t kStopDisabledBit = 1 << 31;
// A stop is enabled, meaning the simulator will stop when meeting the
// instruction, if bit 31 of watched_stops_[code].count is unset.
// The value watched_stops_[code].count & ~(1 << 31) indicates how many times
// the breakpoint was hit or gone through.
struct StopCountAndDesc {
uint32_t count;
char* desc;
};
StopCountAndDesc watched_stops_[kNumOfWatchedStops];
void DebugStart();
};
// When running with the simulator transition into simulated execution at this
// point.
#define CALL_GENERATED_CODE(isolate, entry, p0, p1, p2, p3, p4) \
reinterpret_cast<Object*>(Simulator::current(isolate)->Call( \
FUNCTION_ADDR(entry), 5, (intptr_t)p0, (intptr_t)p1, (intptr_t)p2, \
(intptr_t)p3, (intptr_t)p4))
#define CALL_GENERATED_REGEXP_CODE(isolate, entry, p0, p1, p2, p3, p4, p5, p6, \
p7, p8) \
Simulator::current(isolate)->Call(entry, 10, (intptr_t)p0, (intptr_t)p1, \
(intptr_t)p2, (intptr_t)p3, (intptr_t)p4, \
(intptr_t)p5, (intptr_t)p6, (intptr_t)p7, \
(intptr_t)NULL, (intptr_t)p8)
// The simulator has its own stack. Thus it has a different stack limit from
// the C-based native code. The JS-based limit normally points near the end of
// the simulator stack. When the C-based limit is exhausted we reflect that by
// lowering the JS-based limit as well, to make stack checks trigger.
class SimulatorStack : public v8::internal::AllStatic {
public:
static inline uintptr_t JsLimitFromCLimit(v8::internal::Isolate* isolate,
uintptr_t c_limit) {
return Simulator::current(isolate)->StackLimit(c_limit);
}
static inline uintptr_t RegisterCTryCatch(v8::internal::Isolate* isolate,
uintptr_t try_catch_address) {
Simulator* sim = Simulator::current(isolate);
return sim->PushAddress(try_catch_address);
}
static inline void UnregisterCTryCatch(v8::internal::Isolate* isolate) {
Simulator::current(isolate)->PopAddress();
}
};
} // namespace internal
} // namespace v8
#endif // !defined(USE_SIMULATOR)
#endif // V8_S390_SIMULATOR_S390_H_