# Copyright (C) 2007 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. # # Awk helper script for opcode-gen. # # # Initialization. # BEGIN { MAX_OPCODE = 65535; MAX_PACKED_OPCODE = 511; MAX_PACKED_OPCODE = 255; # TODO: Not for long! initIndexTypes(); initFlags(); if (readBytecodes()) exit 1; deriveOpcodeChains(); createPackedTables(); consumeUntil = ""; emission = ""; } # # General control (must appear above directive handlers). # # Clear out the preexisting output within a directive section. consumeUntil != "" { if (index($0, consumeUntil) != 0) { consumeUntil = ""; print; } next; } # Detect directives. /BEGIN\([a-z-]*\)/ { i = match($0, /BEGIN\([a-z-]*\)/); emission = substr($0, i + 6, RLENGTH - 7); consumeUntil = "END(" emission ")"; emissionHandled = 0; } # Most lines just get copied from the source as-is, including the start # comment for directives. { print; } # # Handlers for all of the directives. # emission == "opcodes" { emissionHandled = 1; for (i = 0; i <= MAX_OPCODE; i++) { if (isUnused(i) || isOptimized(i)) continue; printf(" public static final int %s = 0x%s;\n", constName[i], hex[i]); } } emission == "first-opcodes" { emissionHandled = 1; for (i = 0; i <= MAX_OPCODE; i++) { if (isUnused(i) || isOptimized(i)) continue; if (isFirst[i] == "true") { printf(" // Opcodes.%s\n", constName[i]); } } } emission == "dops" { emissionHandled = 1; for (i = 0; i <= MAX_OPCODE; i++) { if (isUnused(i) || isOptimized(i)) continue; nextOp = nextOpcode[i]; nextOp = (nextOp == -1) ? "NO_NEXT" : constName[nextOp]; printf(" public static final Dop %s =\n" \ " new Dop(Opcodes.%s, Opcodes.%s,\n" \ " Opcodes.%s, Form%s.THE_ONE, %s);\n\n", constName[i], constName[i], family[i], nextOp, format[i], hasResult[i]); } } emission == "opcode-info-defs" { emissionHandled = 1; for (i = 0; i <= MAX_OPCODE; i++) { if (isUnused(i) || isOptimized(i)) continue; itype = toupper(indexType[i]); gsub(/-/, "_", itype); printf(" public static final Info %s =\n" \ " new Info(Opcodes.%s, \"%s\",\n" \ " InstructionCodec.FORMAT_%s, IndexType.%s);\n\n", \ constName[i], constName[i], name[i], toupper(format[i]), itype); } } emission == "dops-init" || emission == "opcode-info-init" { emissionHandled = 1; for (i = 0; i <= MAX_OPCODE; i++) { if (isUnused(i) || isOptimized(i)) continue; printf(" set(%s);\n", constName[i]); } } emission == "libcore-opcodes" { emissionHandled = 1; for (i = 0; i <= MAX_OPCODE; i++) { if (isUnused(i) || isOptimized(i)) continue; printf(" int OP_%-28s = 0x%04x;\n", constName[i], i); } } emission == "libcore-maximum-values" { emissionHandled = 1; printf(" MAXIMUM_VALUE = %d;\n", MAX_OPCODE); printf(" MAXIMUM_PACKED_VALUE = %d;\n", MAX_PACKED_OPCODE); } emission == "libdex-maximum-values" { emissionHandled = 1; printf("#define kMaxOpcodeValue 0x%x\n", MAX_OPCODE); printf("#define kNumPackedOpcodes 0x%x\n", MAX_PACKED_OPCODE + 1); } emission == "libdex-opcode-enum" { emissionHandled = 1; for (i = 0; i <= MAX_PACKED_OPCODE; i++) { printf(" OP_%-28s = 0x%02x,\n", packedConstName[i], i); } } emission == "libdex-goto-table" { emissionHandled = 1; for (i = 0; i <= MAX_PACKED_OPCODE; i++) { content = sprintf(" H(OP_%s),", packedConstName[i]); printf("%-78s\\\n", content); } } emission == "libdex-opcode-names" { emissionHandled = 1; for (i = 0; i <= MAX_PACKED_OPCODE; i++) { printf(" \"%s\",\n", packedName[i]); } } emission == "libdex-widths" { emissionHandled = 1; col = 1; for (i = 0; i <= MAX_PACKED_OPCODE; i++) { value = sprintf("%d,", packedWidth[i]); col = colPrint(value, (i == MAX_PACKED_OPCODE), col, 16, 2, " "); } } emission == "libdex-flags" { emissionHandled = 1; for (i = 0; i <= MAX_PACKED_OPCODE; i++) { value = flagsToC(packedFlags[i]); printf(" %s,\n", value); } } emission == "libdex-formats" { emissionHandled = 1; col = 1; for (i = 0; i <= MAX_PACKED_OPCODE; i++) { value = sprintf("kFmt%s,", packedFormat[i]); col = colPrint(value, (i == MAX_PACKED_OPCODE), col, 7, 9, " "); } } emission == "libdex-index-types" { emissionHandled = 1; col = 1; for (i = 0; i <= MAX_PACKED_OPCODE; i++) { value = sprintf("%s,", indexTypeValues[packedIndexType[i]]); col = colPrint(value, (i == MAX_PACKED_OPCODE), col, 3, 19, " "); } } # Handle the end of directive processing (must appear after the directive # clauses). emission != "" { if (!emissionHandled) { printf("WARNING: unknown tag \"%s\"\n", emission) >"/dev/stderr"; consumeUntil = ""; } emission = ""; } # # Helper functions. # # Helper to print out an element in a multi-column fashion. It returns # the (one-based) column number that the next element will be printed # in. function colPrint(value, isLast, col, numCols, colWidth, linePrefix) { isLast = (isLast || (col == numCols)); printf("%s%-*s%s", (col == 1) ? linePrefix : " ", isLast ? 1 : colWidth, value, isLast ? "\n" : ""); return (col % numCols) + 1; } # Read the bytecode description file. function readBytecodes(i, parts, line, cmd, status, count) { # locals: parts, line, cmd, status, count for (;;) { # Read a line. status = getline line "/dev/stderr"; return 1; } } return 0; } # Define an opcode. function defineOpcode(line, count, parts, idx) { # locals: count, parts, idx count = split(line, parts); if (count != 6) return -1; idx = parseHex(parts[1]); if (idx < 0) return -1; # Extract directly specified values from the line. hex[idx] = parts[1]; name[idx] = parts[2]; format[idx] = parts[3]; hasResult[idx] = (parts[4] == "n") ? "false" : "true"; indexType[idx] = parts[5]; flags[idx] = parts[6]; # Calculate derived values. constName[idx] = toupper(name[idx]); gsub("[/-]", "_", constName[idx]); # Dash and slash become underscore. gsub("[+^]", "", constName[idx]); # Plus and caret are removed. split(name[idx], parts, "/"); family[idx] = toupper(parts[1]); gsub("-", "_", family[idx]); # Dash becomes underscore. gsub("[+^]", "", family[idx]); # Plus and caret are removed. split(format[idx], parts, ""); # Width is the first format char. width[idx] = parts[1]; # This association is used when computing "next" opcodes. familyFormat[family[idx],format[idx]] = idx; # Verify values. if (nextFormat[format[idx]] == "") { printf("unknown format: %s\n", format[idx]) >"/dev/stderr"; return 1; } if (indexTypeValues[indexType[idx]] == "") { printf("unknown index type: %s\n", indexType[idx]) >"/dev/stderr"; return 1; } if (flagsToC(flags[idx]) == "") { printf("bogus flags: %s\n", flags[idx]) >"/dev/stderr"; return 1; } return 0; } # Define a format family. function defineFormat(line, count, parts, i) { # locals: count, parts, i count = split(line, parts); if (count < 1) return -1; formats[parts[1]] = line; parts[count + 1] = "none"; for (i = 1; i <= count; i++) { nextFormat[parts[i]] = parts[i + 1]; } return 0; } # Produce the nextOpcode and isFirst arrays. The former indicates, for # each opcode, which one should be tried next when doing instruction # fitting. The latter indicates which opcodes are at the head of an # instruction fitting chain. function deriveOpcodeChains(i, op) { # locals: i, op for (i = 0; i <= MAX_OPCODE; i++) { if (isUnused(i)) continue; isFirst[i] = "true"; } for (i = 0; i <= MAX_OPCODE; i++) { if (isUnused(i)) continue; op = findNextOpcode(i); nextOpcode[i] = op; if (op != -1) { isFirst[op] = "false"; } } } # Given an opcode by index, find the next opcode in the same family # (that is, with the same base name) to try when matching instructions # to opcodes. This simply walks the nextFormat chain looking for a # match. This returns the index of the matching opcode or -1 if there # is none. function findNextOpcode(idx, fam, fmt, result) { # locals: fam, fmt, result fam = family[idx]; fmt = format[idx]; # Not every opcode has a version with every possible format, so # we have to iterate down the chain until we find one or run out of # formats to try. for (fmt = nextFormat[format[idx]]; fmt != "none"; fmt = nextFormat[fmt]) { result = familyFormat[fam,fmt]; if (result != "") { return result; } } return -1; } # Construct the tables of info indexed by packed opcode. The packed opcode # values are in the range 0-0x1ff, whereas the unpacked opcodes sparsely # span the range 0-0xffff. function createPackedTables(i, op) { # locals: i, op for (i = 0; i <= MAX_PACKED_OPCODE; i++) { op = unpackOpcode(i); if (isUnused(op)) { packedName[i] = unusedName(op); packedConstName[i] = unusedConstName(op); packedFormat[i] = "00x"; packedFlags[i] = 0; packedWidth[i] = 0; packedIndexType[i] = "unknown"; } else { packedName[i] = name[op]; packedConstName[i] = constName[op]; packedFormat[i] = format[op]; packedFlags[i] = flags[op]; packedWidth[i] = width[op]; packedIndexType[i] = indexType[op]; } } } # Given a packed opcode, returns the raw (unpacked) opcode value. function unpackOpcode(idx) { # Note: This must be the inverse of the corresponding code in # libdex/DexOpcodes.h. if (idx <= 255) { return idx; } else { idx -= 256; return (idx * 256) + 255; } } # Returns the "unused" name of the given opcode (by index). # That is, this is the human-oriented name to use for an opcode # definition in cases # where the opcode isn't used. function unusedName(idx) { if (idx <= 255) { return sprintf("unused-%02x", idx); } else { return sprintf("unused-%04x", idx); } } # Returns the "unused" constant name of the given opcode (by index). # That is, this is the name to use for a constant definition in cases # where the opcode isn't used. function unusedConstName(idx) { if (idx <= 255) { return toupper(sprintf("UNUSED_%02x", idx)); } else { return toupper(sprintf("UNUSED_%04x", idx)); } } # Convert a hex value to an int. function parseHex(hex, result, chars, count, c, i) { # locals: result, chars, count, c, i hex = tolower(hex); count = split(hex, chars, ""); result = 0; for (i = 1; i <= count; i++) { c = index("0123456789abcdef", chars[i]); if (c == 0) { printf("bogus hex value: %s\n", hex) >"/dev/stderr"; return -1; } result = (result * 16) + c - 1; } return result; } # Initialize the indexTypes data. function initIndexTypes() { indexTypeValues["unknown"] = "kIndexUnknown"; indexTypeValues["none"] = "kIndexNone"; indexTypeValues["varies"] = "kIndexVaries"; indexTypeValues["type-ref"] = "kIndexTypeRef"; indexTypeValues["string-ref"] = "kIndexStringRef"; indexTypeValues["method-ref"] = "kIndexMethodRef"; indexTypeValues["field-ref"] = "kIndexFieldRef"; indexTypeValues["inline-method"] = "kIndexInlineMethod"; indexTypeValues["vtable-offset"] = "kIndexVtableOffset"; indexTypeValues["field-offset"] = "kIndexFieldOffset"; indexTypeValues["method-and-proto-ref"] = "kIndexMethodAndProtoRef"; indexTypeValues["call-site-ref"] = "kIndexCallSiteRef"; indexTypeValues["method-handle-ref"] = "kIndexMethodHandleRef"; indexTypeValues["proto-ref"] = "kIndexProtoRef"; } # Initialize the flags data. function initFlags() { flagValues["branch"] = "kInstrCanBranch"; flagValues["continue"] = "kInstrCanContinue"; flagValues["switch"] = "kInstrCanSwitch"; flagValues["throw"] = "kInstrCanThrow"; flagValues["return"] = "kInstrCanReturn"; flagValues["invoke"] = "kInstrInvoke"; flagValues["optimized"] = "0"; # Not represented in C output flagValues["0"] = "0"; } # Translate the given flags into the equivalent C expression. Returns # "" on error. function flagsToC(f, parts, result, i) { # locals: parts, result, i count = split(f, parts, /\|/); # Split input at pipe characters. result = "0"; for (i = 1; i <= count; i++) { f = flagValues[parts[i]]; if (f == "") { printf("bogus flag: %s\n", f) >"/dev/stderr"; return ""; # Bogus flag name. } else if (f == "0") { # Nothing to append for this case. } else if (result == "0") { result = f; } else { result = result "|" f; } } return result; } # Returns true if the given opcode (by index) is an "optimized" opcode. function isOptimized(idx, parts, f) { # locals: parts, f split(flags[idx], parts, /\|/); # Split flags[idx] at pipes. for (f in parts) { if (parts[f] == "optimized") return 1; } return 0; } # Returns true if there is no definition for the given opcode (by index). function isUnused(idx) { return (name[idx] == ""); }