Implementation of Hash Extern

Signed-off-by: Komal, Jain <[email protected]>

backends/tc/ebpfCodeGen.cpp

@@ -248,7 +248,6 @@ void PNAArchTC::emitHeader(EBPF::CodeBuilder *builder) const {
     emitP4TCFilterFields(builder);
     //  BPF map definitions.
     emitInstances(builder);
-    EBPFHashAlgorithmTypeFactoryPNA::instance()->emitGlobals(builder);
 }
 
 // =====================TCIngressPipelinePNA=============================
@@ -1394,6 +1393,11 @@ bool ConvertToEBPFParserPNA::preorder(const IR::P4ValueSet *pvs) {
     return false;
 }
 
+void EBPFControlPNA::emit(EBPF::CodeBuilder *builder) {
+    for (auto h : pna_hashes) h.second->emitVariables(builder);
+    EBPF::EBPFControl::emit(builder);
+}
+
 // =====================ConvertToEBPFControlPNA=============================
 bool ConvertToEBPFControlPNA::preorder(const IR::ControlBlock *ctrl) {
     control = new EBPFControlPNA(program, ctrl, parserHeaders);
@@ -1491,8 +1495,8 @@ bool ConvertToEBPFControlPNA::preorder(const IR::ExternBlock *instance) {
     cstring name = EBPF::EBPFObject::externalName(di);
     cstring typeName = instance->type->getName().name;
     if (typeName == "Hash") {
-        auto hash = new EBPF::EBPFHashPSA(program, di, name);
-        control->hashes.emplace(name, hash);
+        auto hash = new EBPFHashPNA(program, di, name);
+        control->pna_hashes.emplace(name, hash);
     } else if (typeName == "Register") {
         auto reg = new EBPFRegisterPNA(program, name, di, control->codeGen);
         control->pna_registers.emplace(name, reg);
@@ -2009,7 +2013,7 @@ void ControlBodyTranslatorPNA::processMethod(const P4::ExternMethod *method) {
         pna_meter->emitExecute(builder, method, this, nullptr);
         return;
     } else if (declType->name.name == "Hash") {
-        auto hash = control->to<EBPF::EBPFControlPSA>()->getHash(name);
+        auto hash = pnaControl->getHash(name);
         hash->processMethod(builder, method->method->name.name, method->expr, this);
         return;
     } else {
@@ -2048,7 +2052,7 @@ bool ControlBodyTranslatorPNA::preorder(const IR::AssignmentStatement *a) {
             return false;
         } else if (ext->originalExternType->name.name == "Hash") {
             cstring name = EBPF::EBPFObject::externalName(ext->object);
-            auto hash = control->to<EBPF::EBPFControlPSA>()->getHash(name);
+            auto hash = pnaControl->getHash(name);
             // Before assigning a value to a left expression we have to calculate a hash.
             // Then the hash value is stored in a registerVar variable.
             hash->calculateHash(builder, ext->expr, this);
@@ -2380,160 +2384,16 @@ void DeparserHdrEmitTranslatorPNA::emitField(EBPF::CodeBuilder *builder, cstring
 
 EBPF::EBPFHashAlgorithmPSA *EBPFHashAlgorithmTypeFactoryPNA::create(
     int type, const EBPF::EBPFProgram *program, cstring name) {
-    if (type == EBPF::EBPFHashAlgorithmPSA::HashAlgorithm::ONES_COMPLEMENT16 ||
-        type == EBPF::EBPFHashAlgorithmPSA::HashAlgorithm::TARGET_DEFAULT) {
+    if (type == EBPF::EBPFHashAlgorithmPSA::HashAlgorithm::CRC16) {
+        return new CRCChecksumAlgorithmPNA(program, name, 16);
+    } else if (type == EBPF::EBPFHashAlgorithmPSA::HashAlgorithm::CRC32) {
+        return new CRCChecksumAlgorithmPNA(program, name, 32);
+    } else if (type == EBPF::EBPFHashAlgorithmPSA::HashAlgorithm::ONES_COMPLEMENT16 ||
+               type == EBPF::EBPFHashAlgorithmPSA::HashAlgorithm::TARGET_DEFAULT) {
         return new InternetChecksumAlgorithmPNA(program, name);
     }
 
     return nullptr;
 }
 
-void CRCChecksumAlgorithmPNA::emitUpdateMethod(EBPF::CodeBuilder *builder, int crcWidth) {
-    // Note that this update method is optimized for our CRC16 and CRC32, custom
-    // version may require other method of update. When data_size <= 64 bits,
-    // applies host byte order for input data, otherwise network byte order is expected.
-    if (crcWidth == 16) {
-        // This function calculates CRC16 by definition, it is bit by bit. If input data has more
-        // than 64 bit, the outer loop process bytes in network byte order - data pointer is
-        // incremented. For data shorter than or equal 64 bits, bytes are processed in little endian
-        // byte order - data pointer is decremented by outer loop in this case.
-        // There is no need for lookup table.
-        const char *code =
-            "static __always_inline\n"
-            "void crc16_update(u16 * reg, const u8 * data, "
-            "u16 data_size, const u16 poly) {\n"
-            "    if (data_size <= 8)\n"
-            "        data += data_size - 1;\n"
-            "    #pragma clang loop unroll(full)\n"
-            "    for (u16 i = 0; i < data_size; i++) {\n"
-            "        bpf_trace_message(\"CRC16: data byte: %x\\n\", *data);\n"
-            "        *reg ^= *data;\n"
-            "        for (u8 bit = 0; bit < 8; bit++) {\n"
-            "            *reg = (*reg) & 1 ? ((*reg) >> 1) ^ poly : (*reg) >> 1;\n"
-            "        }\n"
-            "        if (data_size <= 8)\n"
-            "            data--;\n"
-            "        else\n"
-            "            data++;\n"
-            "    }\n"
-            "}";
-        builder->appendLine(code);
-    } else if (crcWidth == 32) {
-        // This function calculates CRC32 using two optimisations: slice-by-8 and Standard
-        // Implementation. Both algorithms have to properly handle byte order depending on data
-        // length. There are four cases which must be handled:
-        // 1. Data size below 8 bytes - calculated using Standard Implementation in little endian
-        //    byte order.
-        // 2. Data size equal to 8 bytes - calculated using slice-by-8 in little endian byte order.
-        // 3. Data size more than 8 bytes and multiply of 8 bytes - calculated using slice-by-8 in
-        //    big endian byte order.
-        // 4. Data size more than 8 bytes and not multiply of 8 bytes - calculated using slice-by-8
-        //    and Standard Implementation both in big endian byte order.
-        // Lookup table is necessary for both algorithms.
-        const char *code =
-            "static __always_inline\n"
-            "void crc32_update(u32 * reg, const u8 * data, u16 data_size, const u32 poly) {\n"
-            "    u32* current = (u32*) data;\n"
-            "    u32 index = 0;\n"
-            "    u32 lookup_key = 0;\n"
-            "    u32 lookup_value = 0;\n"
-            "    u32 lookup_value1 = 0;\n"
-            "    u32 lookup_value2 = 0;\n"
-            "    u32 lookup_value3 = 0;\n"
-            "    u32 lookup_value4 = 0;\n"
-            "    u32 lookup_value5 = 0;\n"
-            "    u32 lookup_value6 = 0;\n"
-            "    u32 lookup_value7 = 0;\n"
-            "    u32 lookup_value8 = 0;\n"
-            "    u16 tmp = 0;\n"
-            "    if (crc32_table != NULL) {\n"
-            "        for (u16 i = data_size; i >= 8; i -= 8) {\n"
-            "            /* Vars one and two will have swapped byte order if data_size == 8 */\n"
-            "            if (data_size == 8) current = (u32 *)(data + 4);\n"
-            "            bpf_trace_message(\"CRC32: data dword: %x\\n\", *current);\n"
-            "            u32 one = (data_size == 8 ? __builtin_bswap32(*current--) : *current++) ^ "
-            "*reg;\n"
-            "            bpf_trace_message(\"CRC32: data dword: %x\\n\", *current);\n"
-            "            u32 two = (data_size == 8 ? __builtin_bswap32(*current--) : *current++);\n"
-            "            lookup_key = (one & 0x000000FF);\n"
-            "            lookup_value8 = crc32_table[(u16)(1792 + (u8)lookup_key)];\n"
-            "            lookup_key = (one >> 8) & 0x000000FF;\n"
-            "            lookup_value7 = crc32_table[(u16)(1536 + (u8)lookup_key)];\n"
-            "            lookup_key = (one >> 16) & 0x000000FF;\n"
-            "            lookup_value6 = crc32_table[(u16)(1280 + (u8)lookup_key)];\n"
-            "            lookup_key = one >> 24;\n"
-            "            lookup_value5 = crc32_table[(u16)(1024 + (u8)(lookup_key))];\n"
-            "            lookup_key = (two & 0x000000FF);\n"
-            "            lookup_value4 = crc32_table[(u16)(768 + (u8)lookup_key)];\n"
-            "            lookup_key = (two >> 8) & 0x000000FF;\n"
-            "            lookup_value3 = crc32_table[(u16)(512 + (u8)lookup_key)];\n"
-            "            lookup_key = (two >> 16) & 0x000000FF;\n"
-            "            lookup_value2 = crc32_table[(u16)(256 + (u8)lookup_key)];\n"
-            "            lookup_key = two >> 24;\n"
-            "            lookup_value1 = crc32_table[(u8)(lookup_key)];\n"
-            "            *reg = lookup_value8 ^ lookup_value7 ^ lookup_value6 ^ lookup_value5 ^\n"
-            "                   lookup_value4 ^ lookup_value3 ^ lookup_value2 ^ lookup_value1;\n"
-            "            tmp += 8;\n"
-            "        }\n"
-            "        volatile int std_algo_lookup_key = 0;\n"
-            "        if (data_size < 8) {\n"
-            // Standard Implementation for little endian byte order
-            "            unsigned char *currentChar = (unsigned char *) current;\n"
-            "            currentChar += data_size - 1;\n"
-            "            for (u16 i = tmp; i < data_size; i++) {\n"
-            "                bpf_trace_message(\"CRC32: data byte: %x\\n\", *currentChar);\n"
-            "                std_algo_lookup_key = (u32)(((*reg) & 0xFF) ^ *currentChar--);\n"
-            "                if (std_algo_lookup_key >= 0) {\n"
-            "                    lookup_value = "
-            "crc32_table[(u8)(std_algo_lookup_key & 255)];\n"
-            "                }\n"
-            "                *reg = ((*reg) >> 8) ^ lookup_value;\n"
-            "            }\n"
-            "        } else {\n"
-            // Standard Implementation for big endian byte order
-            "            /* Consume data not processed by slice-by-8 algorithm above, "
-            "these data are in network byte order */\n"
-            "            unsigned char *currentChar = (unsigned char *) current;\n"
-            "            for (u16 i = tmp; i < data_size; i++) {\n"
-            "                bpf_trace_message(\"CRC32: data byte: %x\\n\", *currentChar);\n"
-            "                std_algo_lookup_key = (u32)(((*reg) & 0xFF) ^ *currentChar++);\n"
-            "                if (std_algo_lookup_key >= 0) {\n"
-            "                    lookup_value = "
-            "crc32_table[(u8)(std_algo_lookup_key & 255)];\n"
-            "                }\n"
-            "                *reg = ((*reg) >> 8) ^ lookup_value;\n"
-            "            }\n"
-            "        }\n"
-            "    }\n"
-            "}";
-        builder->appendLine(code);
-    }
-}
-
-// ===========================CRC16ChecksumAlgorithmPNA===========================
-
-void CRC16ChecksumAlgorithmPNA::emitGlobals(EBPF::CodeBuilder *builder) {
-    CRCChecksumAlgorithmPNA::emitUpdateMethod(builder, 16);
-
-    const char *code =
-        "static __always_inline "
-        "u16 crc16_finalize(u16 reg) {\n"
-        "    return reg;\n"
-        "}";
-    builder->appendLine(code);
-}
-
-// ===========================CRC32ChecksumAlgorithmPNA===========================
-
-void CRC32ChecksumAlgorithmPNA::emitGlobals(EBPF::CodeBuilder *builder) {
-    CRCChecksumAlgorithmPNA::emitUpdateMethod(builder, 32);
-
-    const char *code =
-        "static __always_inline "
-        "u32 crc32_finalize(u32 reg) {\n"
-        "    return reg ^ 0xFFFFFFFF;\n"
-        "}";
-    builder->appendLine(code);
-}
-
 }  // namespace P4::TC

backends/tc/ebpfCodeGen.h

@@ -28,6 +28,7 @@ using namespace P4::literals;
 class ConvertToBackendIR;
 class EBPFPnaParser;
 class EBPFRegisterPNA;
+class EBPFHashPNA;
 
 //  Similar to class PSAEbpfGenerator in backends/ebpf/psa/ebpfPsaGen.h
 
@@ -279,6 +280,7 @@ class EBPFControlPNA : public EBPF::EBPFControlPSA {
  public:
     bool addExternDeclaration = false;
     std::map<cstring, EBPFRegisterPNA *> pna_registers;
+    std::map<cstring, EBPFHashPNA *> pna_hashes;
 
     EBPFControlPNA(const EBPF::EBPFProgram *program, const IR::ControlBlock *control,
                    const IR::Parameter *parserHeaders)
@@ -289,6 +291,11 @@ class EBPFControlPNA : public EBPF::EBPFControlPSA {
         BUG_CHECK(result != nullptr, "No register named %1%", name);
         return result;
     }
+    EBPFHashPNA *getHash(cstring name) const {
+        auto result = ::P4::get(pna_hashes, name);
+        BUG_CHECK(result != nullptr, "No hash named %1%", name);
+        return result;
+    }
     void emitExternDefinition(EBPF::CodeBuilder *builder) {
         if (addExternDeclaration) {
             builder->emitIndent();
@@ -300,6 +307,7 @@ class EBPFControlPNA : public EBPF::EBPFControlPSA {
         }
     }
     void emitTableTypes(EBPF::CodeBuilder *builder) { EBPF::EBPFControl::emitTableTypes(builder); }
+    void emit(EBPF::CodeBuilder *builder);
 };
 
 // Similar to class ConvertToEBPFControlPSA in backends/ebpf/psa/ebpfPsaGen.h
@@ -415,56 +423,13 @@ class DeparserHdrEmitTranslatorPNA : public EBPF::DeparserPrepareBufferTranslato
                    unsigned alignment, EBPF::EBPFType *type, bool isMAC);
 };
 
-class CRCChecksumAlgorithmPNA : public EBPF::CRCChecksumAlgorithm {
- public:
-    CRCChecksumAlgorithmPNA(const EBPF::EBPFProgram *program, cstring name, int width)
-        : EBPF::CRCChecksumAlgorithm(program, name, width) {}
-
-    static void emitUpdateMethod(EBPF::CodeBuilder *builder, int crcWidth);
-};
-
-class CRC16ChecksumAlgorithmPNA : public CRCChecksumAlgorithmPNA {
- public:
-    CRC16ChecksumAlgorithmPNA(const EBPF::EBPFProgram *program, cstring name)
-        : CRCChecksumAlgorithmPNA(program, name, 16) {
-        initialValue = "0"_cs;
-        // We use a 0x8005 polynomial.
-        // 0xA001 comes from 0x8005 value bits reflection.
-        polynomial = "0xA001"_cs;
-        updateMethod = "crc16_update"_cs;
-        finalizeMethod = "crc16_finalize"_cs;
-    }
-
-    static void emitGlobals(EBPF::CodeBuilder *builder);
-};
-
-class CRC32ChecksumAlgorithmPNA : public CRCChecksumAlgorithmPNA {
- public:
-    CRC32ChecksumAlgorithmPNA(const EBPF::EBPFProgram *program, cstring name)
-        : CRCChecksumAlgorithmPNA(program, name, 32) {
-        initialValue = "0xffffffff"_cs;
-        // We use a 0x04C11DB7 polynomial.
-        // 0xEDB88320 comes from 0x04C11DB7 value bits reflection.
-        polynomial = "0xEDB88320"_cs;
-        updateMethod = "crc32_update"_cs;
-        finalizeMethod = "crc32_finalize"_cs;
-    }
-
-    static void emitGlobals(EBPF::CodeBuilder *builder);
-};
-
 class EBPFHashAlgorithmTypeFactoryPNA : public EBPF::EBPFHashAlgorithmTypeFactoryPSA {
  public:
     static EBPFHashAlgorithmTypeFactoryPNA *instance() {
         static EBPFHashAlgorithmTypeFactoryPNA factory;
         return &factory;
     }
 
-    void emitGlobals(EBPF::CodeBuilder *builder) {
-        CRC16ChecksumAlgorithmPNA::emitGlobals(builder);
-        CRC32ChecksumAlgorithmPNA::emitGlobals(builder);
-    }
-
     EBPF::EBPFHashAlgorithmPSA *create(int type, const EBPF::EBPFProgram *program, cstring name);
 };
 

backends/tc/tcExterns.cpp

@@ -453,6 +453,72 @@ void EBPFDigestPNA::emitInitializer(EBPF::CodeBuilder *builder) const {
     builder->newline();
 }
 
+void EBPFHashPNA::emitVariables(EBPF::CodeBuilder *builder) {
+    if (engine) {
+        engine->emitVariables(builder, declaration);
+    }
+}
+
+void EBPFHashPNA::processMethod(EBPF::CodeBuilder *builder, cstring method,
+                                const IR::MethodCallExpression *expr, Visitor *visitor) {
+    engine->setVisitor(visitor);
+
+    if (method == "get_hash") {
+        BUG_CHECK(expr->arguments->size() == 1 || expr->arguments->size() == 3,
+                  "Expected 1 or 3 arguments: %1%", expr);
+        engine->emitGet(builder);
+    } else {
+        ::P4::error(ErrorType::ERR_UNEXPECTED, "Unexpected method call %1%", expr);
+    }
+}
+
+void EBPFHashPNA::calculateHash(EBPF::CodeBuilder *builder, const IR::MethodCallExpression *expr,
+                                Visitor *visitor) {
+    engine->setVisitor(visitor);
+    engine->emitClear(builder);
+    engine->emitAddData(builder, expr->arguments->size() == 3 ? 1 : 0, expr);
+    builder->newline();
+}
+
+void CRCChecksumAlgorithmPNA::emitGet(EBPF::CodeBuilder *builder) {
+    builder->appendFormat("%s", registerVar.c_str());
+}
+
+void CRCChecksumAlgorithmPNA::emitAddData(EBPF::CodeBuilder *builder, int dataPos,
+                                          const IR::MethodCallExpression *expr) {
+    emitAddData(builder, unpackArguments(expr, dataPos), expr);
+}
+
+void CRCChecksumAlgorithmPNA::emitAddData(EBPF::CodeBuilder *builder,
+                                          const ArgumentsList &arguments,
+                                          const IR::MethodCallExpression *expr) {
+    cstring kfunc;
+    if (crcWidth == 16) {
+        kfunc = expr->arguments->size() == 3 ? "bpf_p4tc_ext_hash_base_crc16"_cs
+                                             : "bpf_p4tc_ext_hash_crc16"_cs;
+    } else {
+        kfunc = expr->arguments->size() == 3 ? "bpf_p4tc_ext_hash_base_crc32"_cs
+                                             : "bpf_p4tc_ext_hash_crc32"_cs;
+    }
+    for (auto field : arguments) {
+        builder->newline();
+        builder->emitIndent();
+        builder->appendFormat("%s(&", kfunc);
+        visitor->visit(field);
+        builder->append(", sizeof(");
+        visitor->visit(field);
+        if (expr->arguments->size() == 3) {
+            builder->append("), ");
+            visitor->visit(expr->arguments->at(0));
+            builder->append(", ");
+            visitor->visit(expr->arguments->at(2));
+            builder->appendFormat(", %s);", registerVar);
+        } else {
+            builder->appendFormat("), %s);", registerVar);
+        }
+    }
+}
+
 void EBPFDigestPNA::emitPushElement(EBPF::CodeBuilder *builder, const IR::Expression *elem,
                                     Inspector *codegen) const {
     emitInitializer(builder);