/*
* Copyright (c) 2010, 2016, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*/
package jdk.vm.ci.code;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.Map;
import jdk.vm.ci.meta.JavaType;
import jdk.vm.ci.meta.MetaUtil;
import jdk.vm.ci.meta.ResolvedJavaMethod;
import jdk.vm.ci.meta.Signature;
Miscellaneous collection of utility methods used by jdk.vm.ci.code
and its clients. /**
* Miscellaneous collection of utility methods used by {@code jdk.vm.ci.code} and its clients.
*/
public class CodeUtil {
public static final String NEW_LINE = String.format("%n");
public static final int K = 1024;
public static final int M = 1024 * 1024;
public static boolean isOdd(int n) {
return (n & 1) == 1;
}
public static boolean isEven(int n) {
return (n & 1) == 0;
}
Checks whether the specified integer is a power of two.
Params: - val – the value to check
Returns: true
if the value is a power of two; false
otherwise
/**
* Checks whether the specified integer is a power of two.
*
* @param val the value to check
* @return {@code true} if the value is a power of two; {@code false} otherwise
*/
public static boolean isPowerOf2(int val) {
return val > 0 && (val & val - 1) == 0;
}
Checks whether the specified long is a power of two.
Params: - val – the value to check
Returns: true
if the value is a power of two; false
otherwise
/**
* Checks whether the specified long is a power of two.
*
* @param val the value to check
* @return {@code true} if the value is a power of two; {@code false} otherwise
*/
public static boolean isPowerOf2(long val) {
return val > 0 && (val & val - 1) == 0;
}
Computes the log (base 2) of the specified integer, rounding down. (E.g log2(8) = 3
, log2(21) = 4
) Params: - val – the value
Returns: the log base 2 of the value
/**
* Computes the log (base 2) of the specified integer, rounding down. (E.g {@code log2(8) = 3},
* {@code log2(21) = 4} )
*
* @param val the value
* @return the log base 2 of the value
*/
public static int log2(int val) {
assert val > 0;
return (Integer.SIZE - 1) - Integer.numberOfLeadingZeros(val);
}
Computes the log (base 2) of the specified long, rounding down. (E.g log2(8) = 3
, log2(21) = 4
) Params: - val – the value
Returns: the log base 2 of the value
/**
* Computes the log (base 2) of the specified long, rounding down. (E.g {@code log2(8) = 3},
* {@code log2(21) = 4})
*
* @param val the value
* @return the log base 2 of the value
*/
public static int log2(long val) {
assert val > 0;
return (Long.SIZE - 1) - Long.numberOfLeadingZeros(val);
}
Narrow an integer value to a given bit width, and return the result as a signed long.
Params: - value – the value
- resultBits – the result bit width
Returns: value
interpreted as resultBits
bit number, encoded as signed long
/**
* Narrow an integer value to a given bit width, and return the result as a signed long.
*
* @param value the value
* @param resultBits the result bit width
* @return {@code value} interpreted as {@code resultBits} bit number, encoded as signed long
*/
public static long narrow(long value, int resultBits) {
long ret = value & mask(resultBits);
return signExtend(ret, resultBits);
}
Sign extend an integer.
Params: - value – the input value
- inputBits – the bit width of the input value
Returns: a signed long with the same value as the signed inputBits
-bit number value
/**
* Sign extend an integer.
*
* @param value the input value
* @param inputBits the bit width of the input value
* @return a signed long with the same value as the signed {@code inputBits}-bit number
* {@code value}
*/
public static long signExtend(long value, int inputBits) {
if (inputBits < 64) {
if ((value >>> (inputBits - 1) & 1) == 1) {
return value | (-1L << inputBits);
} else {
return value & ~(-1L << inputBits);
}
} else {
return value;
}
}
Zero extend an integer.
Params: - value – the input value
- inputBits – the bit width of the input value
Returns: an unsigned long with the same value as the unsigned inputBits
-bit number value
/**
* Zero extend an integer.
*
* @param value the input value
* @param inputBits the bit width of the input value
* @return an unsigned long with the same value as the unsigned {@code inputBits}-bit number
* {@code value}
*/
public static long zeroExtend(long value, int inputBits) {
if (inputBits < 64) {
return value & ~(-1L << inputBits);
} else {
return value;
}
}
Convert an integer to long.
Params: - value – the input value
- inputBits – the bit width of the input value
- unsigned – whether the values should be interpreted as signed or unsigned
Returns: a long with the same value as the inputBits
-bit number value
/**
* Convert an integer to long.
*
* @param value the input value
* @param inputBits the bit width of the input value
* @param unsigned whether the values should be interpreted as signed or unsigned
* @return a long with the same value as the {@code inputBits}-bit number {@code value}
*/
public static long convert(long value, int inputBits, boolean unsigned) {
if (unsigned) {
return zeroExtend(value, inputBits);
} else {
return signExtend(value, inputBits);
}
}
Get a bitmask with the low bits
bit set and the high 64 - bits
bit clear. /**
* Get a bitmask with the low {@code bits} bit set and the high {@code 64 - bits} bit clear.
*/
public static long mask(int bits) {
assert 0 <= bits && bits <= 64;
if (bits == 64) {
return 0xffffffffffffffffL;
} else {
return (1L << bits) - 1;
}
}
Get the minimum value representable in a bits
bit signed integer. /**
* Get the minimum value representable in a {@code bits} bit signed integer.
*/
public static long minValue(int bits) {
assert 0 < bits && bits <= 64;
return -1L << (bits - 1);
}
Get the maximum value representable in a bits
bit signed integer. /**
* Get the maximum value representable in a {@code bits} bit signed integer.
*/
public static long maxValue(int bits) {
assert 0 < bits && bits <= 64;
return mask(bits - 1);
}
Formats the values in a frame as a tabulated string.
Params: - frame –
Returns: the values in frame
as a tabulated string
/**
* Formats the values in a frame as a tabulated string.
*
* @param frame
* @return the values in {@code frame} as a tabulated string
*/
public static String tabulateValues(BytecodeFrame frame) {
int cols = Math.max(frame.numLocals, Math.max(frame.numStack, frame.numLocks));
assert cols > 0;
ArrayList<Object> cells = new ArrayList<>();
cells.add("");
for (int i = 0; i < cols; i++) {
cells.add(i);
}
cols++;
if (frame.numLocals != 0) {
cells.add("locals:");
cells.addAll(Arrays.asList(frame.values).subList(0, frame.numLocals));
cells.addAll(Collections.nCopies(cols - frame.numLocals - 1, ""));
}
if (frame.numStack != 0) {
cells.add("stack:");
cells.addAll(Arrays.asList(frame.values).subList(frame.numLocals, frame.numLocals + frame.numStack));
cells.addAll(Collections.nCopies(cols - frame.numStack - 1, ""));
}
if (frame.numLocks != 0) {
cells.add("locks:");
cells.addAll(Arrays.asList(frame.values).subList(frame.numLocals + frame.numStack, frame.values.length));
cells.addAll(Collections.nCopies(cols - frame.numLocks - 1, ""));
}
Object[] cellArray = cells.toArray();
for (int i = 0; i < cellArray.length; i++) {
if ((i % cols) != 0) {
cellArray[i] = "|" + cellArray[i];
}
}
return CodeUtil.tabulate(cellArray, cols, 1, 1);
}
Formats a given table as a string. The value of each cell is produced by String.valueOf(Object)
. Params: - cells – the cells of the table in row-major order
- cols – the number of columns per row
- lpad – the number of space padding inserted before each formatted cell value
- rpad – the number of space padding inserted after each formatted cell value
Returns: a string with one line per row and each column left-aligned
/**
* Formats a given table as a string. The value of each cell is produced by
* {@link String#valueOf(Object)}.
*
* @param cells the cells of the table in row-major order
* @param cols the number of columns per row
* @param lpad the number of space padding inserted before each formatted cell value
* @param rpad the number of space padding inserted after each formatted cell value
* @return a string with one line per row and each column left-aligned
*/
public static String tabulate(Object[] cells, int cols, int lpad, int rpad) {
int rows = (cells.length + (cols - 1)) / cols;
int[] colWidths = new int[cols];
for (int col = 0; col < cols; col++) {
for (int row = 0; row < rows; row++) {
int index = col + (row * cols);
if (index < cells.length) {
Object cell = cells[index];
colWidths[col] = Math.max(colWidths[col], String.valueOf(cell).length());
}
}
}
StringBuilder sb = new StringBuilder();
String nl = NEW_LINE;
for (int row = 0; row < rows; row++) {
for (int col = 0; col < cols; col++) {
int index = col + (row * cols);
if (index < cells.length) {
for (int i = 0; i < lpad; i++) {
sb.append(' ');
}
Object cell = cells[index];
String s = String.valueOf(cell);
int w = s.length();
sb.append(s);
while (w < colWidths[col]) {
sb.append(' ');
w++;
}
for (int i = 0; i < rpad; i++) {
sb.append(' ');
}
}
}
sb.append(nl);
}
return sb.toString();
}
Appends a formatted code position to a StringBuilder
. Params: - sb – the
StringBuilder
to append to - pos – the code position to format and append to
sb
Returns: the value of sb
/**
* Appends a formatted code position to a {@link StringBuilder}.
*
* @param sb the {@link StringBuilder} to append to
* @param pos the code position to format and append to {@code sb}
* @return the value of {@code sb}
*/
public static StringBuilder append(StringBuilder sb, BytecodePosition pos) {
MetaUtil.appendLocation(sb.append("at "), pos.getMethod(), pos.getBCI());
if (pos.getCaller() != null) {
sb.append(NEW_LINE);
append(sb, pos.getCaller());
}
return sb;
}
Appends a formatted frame to a StringBuilder
. Params: - sb – the
StringBuilder
to append to - frame – the frame to format and append to
sb
Returns: the value of sb
/**
* Appends a formatted frame to a {@link StringBuilder}.
*
* @param sb the {@link StringBuilder} to append to
* @param frame the frame to format and append to {@code sb}
* @return the value of {@code sb}
*/
public static StringBuilder append(StringBuilder sb, BytecodeFrame frame) {
MetaUtil.appendLocation(sb.append("at "), frame.getMethod(), frame.getBCI());
assert sb.charAt(sb.length() - 1) == ']';
sb.deleteCharAt(sb.length() - 1);
sb.append(", duringCall: ").append(frame.duringCall).append(", rethrow: ").append(frame.rethrowException).append(']');
if (frame.values != null && frame.values.length > 0) {
sb.append(NEW_LINE);
String table = tabulateValues(frame);
String[] rows = table.split(NEW_LINE);
for (int i = 0; i < rows.length; i++) {
String row = rows[i];
if (!row.trim().isEmpty()) {
sb.append(" ").append(row);
if (i != rows.length - 1) {
sb.append(NEW_LINE);
}
}
}
}
if (frame.caller() != null) {
sb.append(NEW_LINE);
append(sb, frame.caller());
} else if (frame.getCaller() != null) {
sb.append(NEW_LINE);
append(sb, frame.getCaller());
}
return sb;
}
public interface RefMapFormatter {
String formatStackSlot(int frameRefMapIndex);
}
Formats a location present in a reference map.
/**
* Formats a location present in a reference map.
*/
public static class DefaultRefMapFormatter implements RefMapFormatter {
The size of a stack slot.
/**
* The size of a stack slot.
*/
public final int slotSize;
The register used as the frame pointer.
/**
* The register used as the frame pointer.
*/
public final Register fp;
The offset (in bytes) from the slot pointed to by fp
to the slot corresponding to bit 0 in the frame reference map. /**
* The offset (in bytes) from the slot pointed to by {@link #fp} to the slot corresponding
* to bit 0 in the frame reference map.
*/
public final int refMapToFPOffset;
public DefaultRefMapFormatter(int slotSize, Register fp, int refMapToFPOffset) {
this.slotSize = slotSize;
this.fp = fp;
this.refMapToFPOffset = refMapToFPOffset;
}
@Override
public String formatStackSlot(int frameRefMapIndex) {
int refMapOffset = frameRefMapIndex * slotSize;
int fpOffset = refMapOffset + refMapToFPOffset;
if (fpOffset >= 0) {
return fp + "+" + fpOffset;
}
return fp.name + fpOffset;
}
}
public static class NumberedRefMapFormatter implements RefMapFormatter {
@Override
public String formatStackSlot(int frameRefMapIndex) {
return "s" + frameRefMapIndex;
}
public String formatRegister(int regRefMapIndex) {
return "r" + regRefMapIndex;
}
}
Appends a formatted debug info to a StringBuilder
. Params: - sb – the
StringBuilder
to append to - info – the debug info to format and append to
sb
Returns: the value of sb
/**
* Appends a formatted debug info to a {@link StringBuilder}.
*
* @param sb the {@link StringBuilder} to append to
* @param info the debug info to format and append to {@code sb}
* @return the value of {@code sb}
*/
public static StringBuilder append(StringBuilder sb, DebugInfo info, RefMapFormatter formatterArg) {
RefMapFormatter formatter = formatterArg;
if (formatter == null) {
formatter = new NumberedRefMapFormatter();
}
String nl = NEW_LINE;
ReferenceMap refMap = info.getReferenceMap();
if (refMap != null) {
sb.append(refMap.toString());
}
RegisterSaveLayout calleeSaveInfo = info.getCalleeSaveInfo();
if (calleeSaveInfo != null) {
sb.append("callee-save-info:").append(nl);
Map<Integer, Register> map = calleeSaveInfo.slotsToRegisters(true);
for (Map.Entry<Integer, Register> e : map.entrySet()) {
sb.append(" ").append(e.getValue()).append(" -> ").append(formatter.formatStackSlot(e.getKey())).append(nl);
}
}
BytecodeFrame frame = info.frame();
if (frame != null) {
append(sb, frame);
} else if (info.getBytecodePosition() != null) {
append(sb, info.getBytecodePosition());
}
return sb;
}
Create a calling convention from a ResolvedJavaMethod
. /**
* Create a calling convention from a {@link ResolvedJavaMethod}.
*/
public static CallingConvention getCallingConvention(CodeCacheProvider codeCache, CallingConvention.Type type, ResolvedJavaMethod method, ValueKindFactory<?> valueKindFactory) {
Signature sig = method.getSignature();
JavaType retType = sig.getReturnType(null);
int sigCount = sig.getParameterCount(false);
JavaType[] argTypes;
int argIndex = 0;
if (!method.isStatic()) {
argTypes = new JavaType[sigCount + 1];
argTypes[argIndex++] = method.getDeclaringClass();
} else {
argTypes = new JavaType[sigCount];
}
for (int i = 0; i < sigCount; i++) {
argTypes[argIndex++] = sig.getParameterType(i, null);
}
RegisterConfig registerConfig = codeCache.getRegisterConfig();
return registerConfig.getCallingConvention(type, retType, argTypes, valueKindFactory);
}
}