Index: flang/lib/Optimizer/CodeGen/CodeGen.cpp
===================================================================
--- flang/lib/Optimizer/CodeGen/CodeGen.cpp
+++ flang/lib/Optimizer/CodeGen/CodeGen.cpp
@@ -38,6 +38,10 @@
 static constexpr unsigned kAttrPointer = CFI_attribute_pointer;
 static constexpr unsigned kAttrAllocatable = CFI_attribute_allocatable;
 
+static mlir::Type getVoidPtrType(mlir::MLIRContext *context) {
+  return mlir::LLVM::LLVMPointerType::get(mlir::IntegerType::get(context, 8));
+}
+
 static mlir::LLVM::ConstantOp
 genConstantIndex(mlir::Location loc, mlir::Type ity,
                  mlir::ConversionPatternRewriter &rewriter,
@@ -65,6 +69,7 @@
   mlir::Type convertType(mlir::Type ty) const {
     return lowerTy().convertType(ty);
   }
+  mlir::Type voidPtrTy() const { return getVoidPtrType(); }
 
   mlir::Type getVoidPtrType() const {
     return mlir::LLVM::LLVMPointerType::get(
@@ -269,7 +274,7 @@
   using FIROpConversion::FIROpConversion;
 
   mlir::LogicalResult
-  matchAndRewrite(fir::AbsentOp absent, OpAdaptor,
+  matchAndRewrite(fir::AbsentOp absent, OpAdaptor adaptor,
                   mlir::ConversionPatternRewriter &rewriter) const override {
     mlir::Type ty = convertType(absent.getType());
     mlir::Location loc = absent.getLoc();
@@ -604,6 +609,7 @@
     return success();
   }
 };
+} // namespace
 
 static mlir::Type getComplexEleTy(mlir::Type complex) {
   if (auto cc = complex.dyn_cast<mlir::ComplexType>())
@@ -611,6 +617,7 @@
   return complex.cast<fir::ComplexType>().getElementType();
 }
 
+namespace {
 /// Compare complex values
 ///
 /// Per 10.1, the only comparisons available are .EQ. (oeq) and .NE. (une).
@@ -874,6 +881,119 @@
     return failure();
   }
 };
+} // namespace
+
+/// Return the LLVMFuncOp corresponding to the standard malloc call.
+static mlir::LLVM::LLVMFuncOp
+getMalloc(fir::AllocMemOp op, mlir::ConversionPatternRewriter &rewriter) {
+  auto module = op->getParentOfType<mlir::ModuleOp>();
+  if (mlir::LLVM::LLVMFuncOp mallocFunc =
+          module.lookupSymbol<mlir::LLVM::LLVMFuncOp>("malloc"))
+    return mallocFunc;
+  mlir::OpBuilder moduleBuilder(
+      op->getParentOfType<mlir::ModuleOp>().getBodyRegion());
+  auto indexType = mlir::IntegerType::get(op.getContext(), 64);
+  return moduleBuilder.create<mlir::LLVM::LLVMFuncOp>(
+      rewriter.getUnknownLoc(), "malloc",
+      mlir::LLVM::LLVMFunctionType::get(getVoidPtrType(op.getContext()),
+                                        indexType,
+                                        /*isVarArg=*/false));
+}
+
+/// Helper function for generating the LLVM IR that computes the size
+/// in bytes for a derived type.
+static mlir::Value
+computeDerivedTypeSize(mlir::Location loc, mlir::Type ptrTy, mlir::Type idxTy,
+                       mlir::ConversionPatternRewriter &rewriter) {
+  auto nullPtr = rewriter.create<mlir::LLVM::NullOp>(loc, ptrTy);
+  mlir::Value one = genConstantIndex(loc, idxTy, rewriter, 1);
+  llvm::SmallVector<mlir::Value> args{nullPtr, one};
+  auto gep = rewriter.create<mlir::LLVM::GEPOp>(loc, ptrTy, args);
+  return rewriter.create<mlir::LLVM::PtrToIntOp>(loc, idxTy, gep);
+}
+
+namespace {
+/// Lower a `fir.allocmem` instruction into `llvm.call @malloc`
+struct AllocMemOpConversion : public FIROpConversion<fir::AllocMemOp> {
+  using FIROpConversion::FIROpConversion;
+
+  mlir::LogicalResult
+  matchAndRewrite(fir::AllocMemOp heap, OpAdaptor adaptor,
+                  mlir::ConversionPatternRewriter &rewriter) const override {
+    mlir::Type ty = convertType(heap.getType());
+    mlir::LLVM::LLVMFuncOp mallocFunc = getMalloc(heap, rewriter);
+    mlir::Location loc = heap.getLoc();
+    auto ity = lowerTy().indexType();
+    if (auto recTy = fir::unwrapSequenceType(heap.getAllocatedType())
+                         .dyn_cast<fir::RecordType>())
+      if (recTy.getNumLenParams() != 0) {
+        TODO(loc,
+             "fir.allocmem codegen of derived type with length parameters");
+        return failure();
+      }
+    mlir::Value size = genTypeSizeInBytes(loc, ity, rewriter, ty);
+    for (mlir::Value opnd : adaptor.getOperands())
+      size = rewriter.create<mlir::LLVM::MulOp>(
+          loc, ity, size, integerCast(loc, rewriter, ity, opnd));
+    heap->setAttr("callee", mlir::SymbolRefAttr::get(mallocFunc));
+    auto malloc = rewriter.create<mlir::LLVM::CallOp>(
+        loc, ::getVoidPtrType(heap.getContext()), size, heap->getAttrs());
+    rewriter.replaceOpWithNewOp<mlir::LLVM::BitcastOp>(heap, ty,
+                                                       malloc.getResult(0));
+    return success();
+  }
+
+  // Compute the (allocation) size of the allocmem type in bytes.
+  mlir::Value genTypeSizeInBytes(mlir::Location loc, mlir::Type idxTy,
+                                 mlir::ConversionPatternRewriter &rewriter,
+                                 mlir::Type llTy) const {
+    // Use the primitive size, if available.
+    auto ptrTy = llTy.dyn_cast<mlir::LLVM::LLVMPointerType>();
+    if (auto size =
+            mlir::LLVM::getPrimitiveTypeSizeInBits(ptrTy.getElementType()))
+      return genConstantIndex(loc, idxTy, rewriter, size / 8);
+
+    // Otherwise, generate the GEP trick in LLVM IR to compute the size.
+    return computeDerivedTypeSize(loc, ptrTy, idxTy, rewriter);
+  }
+};
+} // namespace
+
+/// Return the LLVMFuncOp corresponding to the standard free call.
+static mlir::LLVM::LLVMFuncOp
+getFree(fir::FreeMemOp op, mlir::ConversionPatternRewriter &rewriter) {
+  auto module = op->getParentOfType<mlir::ModuleOp>();
+  if (mlir::LLVM::LLVMFuncOp freeFunc =
+          module.lookupSymbol<mlir::LLVM::LLVMFuncOp>("free"))
+    return freeFunc;
+  mlir::OpBuilder moduleBuilder(module.getBodyRegion());
+  auto voidType = mlir::LLVM::LLVMVoidType::get(op.getContext());
+  return moduleBuilder.create<mlir::LLVM::LLVMFuncOp>(
+      rewriter.getUnknownLoc(), "free",
+      mlir::LLVM::LLVMFunctionType::get(voidType,
+                                        getVoidPtrType(op.getContext()),
+                                        /*isVarArg=*/false));
+}
+
+namespace {
+/// Lower a `fir.freemem` instruction into `llvm.call @free`
+struct FreeMemOpConversion : public FIROpConversion<fir::FreeMemOp> {
+  using FIROpConversion::FIROpConversion;
+
+  mlir::LogicalResult
+  matchAndRewrite(fir::FreeMemOp freemem, OpAdaptor adaptor,
+                  mlir::ConversionPatternRewriter &rewriter) const override {
+    mlir::LLVM::LLVMFuncOp freeFunc = getFree(freemem, rewriter);
+    mlir::Location loc = freemem.getLoc();
+    auto bitcast = rewriter.create<mlir::LLVM::BitcastOp>(
+        freemem.getLoc(), voidPtrTy(), adaptor.getOperands()[0]);
+    freemem->setAttr("callee", mlir::SymbolRefAttr::get(freeFunc));
+    rewriter.create<mlir::LLVM::CallOp>(
+        loc, mlir::TypeRange{}, mlir::ValueRange{bitcast}, freemem->getAttrs());
+    rewriter.eraseOp(freemem);
+    return success();
+  }
+};
 
 /// Convert `fir.end`
 struct FirEndOpConversion : public FIROpConversion<fir::FirEndOp> {
@@ -983,11 +1103,12 @@
     return mlir::LLVM::Linkage::External;
   }
 };
+} // namespace
 
-void genCondBrOp(mlir::Location loc, mlir::Value cmp, mlir::Block *dest,
-                 Optional<mlir::ValueRange> destOps,
-                 mlir::ConversionPatternRewriter &rewriter,
-                 mlir::Block *newBlock) {
+static void genCondBrOp(mlir::Location loc, mlir::Value cmp, mlir::Block *dest,
+                        Optional<mlir::ValueRange> destOps,
+                        mlir::ConversionPatternRewriter &rewriter,
+                        mlir::Block *newBlock) {
   if (destOps.hasValue())
     rewriter.create<mlir::LLVM::CondBrOp>(loc, cmp, dest, destOps.getValue(),
                                           newBlock, mlir::ValueRange());
@@ -996,8 +1117,8 @@
 }
 
 template <typename A, typename B>
-void genBrOp(A caseOp, mlir::Block *dest, Optional<B> destOps,
-             mlir::ConversionPatternRewriter &rewriter) {
+static void genBrOp(A caseOp, mlir::Block *dest, Optional<B> destOps,
+                    mlir::ConversionPatternRewriter &rewriter) {
   if (destOps.hasValue())
     rewriter.replaceOpWithNewOp<mlir::LLVM::BrOp>(caseOp, destOps.getValue(),
                                                   dest);
@@ -1005,9 +1126,10 @@
     rewriter.replaceOpWithNewOp<mlir::LLVM::BrOp>(caseOp, llvm::None, dest);
 }
 
-void genCaseLadderStep(mlir::Location loc, mlir::Value cmp, mlir::Block *dest,
-                       Optional<mlir::ValueRange> destOps,
-                       mlir::ConversionPatternRewriter &rewriter) {
+static void genCaseLadderStep(mlir::Location loc, mlir::Value cmp,
+                              mlir::Block *dest,
+                              Optional<mlir::ValueRange> destOps,
+                              mlir::ConversionPatternRewriter &rewriter) {
   auto *thisBlock = rewriter.getInsertionBlock();
   auto *newBlock = createBlock(rewriter, dest);
   rewriter.setInsertionPointToEnd(thisBlock);
@@ -1015,6 +1137,7 @@
   rewriter.setInsertionPointToEnd(newBlock);
 }
 
+namespace {
 /// Conversion of `fir.select_case`
 ///
 /// The `fir.select_case` operation is converted to a if-then-else ladder.
@@ -1099,11 +1222,12 @@
     return success();
   }
 };
+} // namespace
 
 template <typename OP>
-void selectMatchAndRewrite(fir::LLVMTypeConverter &lowering, OP select,
-                           typename OP::Adaptor adaptor,
-                           mlir::ConversionPatternRewriter &rewriter) {
+static void selectMatchAndRewrite(fir::LLVMTypeConverter &lowering, OP select,
+                                  typename OP::Adaptor adaptor,
+                                  mlir::ConversionPatternRewriter &rewriter) {
   unsigned conds = select.getNumConditions();
   auto cases = select.getCases().getValue();
   mlir::Value selector = adaptor.selector();
@@ -1148,6 +1272,7 @@
       /*branchWeights=*/ArrayRef<int32_t>());
 }
 
+namespace {
 /// conversion of fir::SelectOp to an if-then-else ladder
 struct SelectOpConversion : public FIROpConversion<fir::SelectOp> {
   using FIROpConversion::FIROpConversion;
@@ -1295,6 +1420,7 @@
     return success();
   }
 };
+} // namespace
 
 /// Common base class for embox to descriptor conversion.
 template <typename OP>
@@ -1638,18 +1764,6 @@
   return rewriter.create<mlir::LLVM::SelectOp>(loc, cmp, extent, zero);
 }
 
-/// Helper function for generating the LLVM IR that computes the size
-/// in bytes for a derived type.
-static mlir::Value
-computeDerivedTypeSize(mlir::Location loc, mlir::Type ptrTy, mlir::Type idxTy,
-                       mlir::ConversionPatternRewriter &rewriter) {
-  auto nullPtr = rewriter.create<mlir::LLVM::NullOp>(loc, ptrTy);
-  mlir::Value one = genConstantIndex(loc, idxTy, rewriter, 1);
-  llvm::SmallVector<mlir::Value> args{nullPtr, one};
-  auto gep = rewriter.create<mlir::LLVM::GEPOp>(loc, ptrTy, args);
-  return rewriter.create<mlir::LLVM::PtrToIntOp>(loc, idxTy, gep);
-}
-
 /// Create a generic box on a memory reference. This conversions lowers the
 /// abstract box to the appropriate, initialized descriptor.
 struct EmboxOpConversion : public EmboxCommonConversion<fir::EmboxOp> {
@@ -1915,6 +2029,7 @@
   }
 };
 
+namespace {
 /// Extract a subobject value from an ssa-value of aggregate type
 struct ExtractValueOpConversion
     : public FIROpAndTypeConversion<fir::ExtractValueOp>,
@@ -2025,6 +2140,7 @@
     return success();
   }
 };
+} // namespace
 
 /// XArrayCoor is the address arithmetic on a dynamically shaped, sliced,
 /// shifted etc. array.
@@ -2194,9 +2310,10 @@
 
 /// Generate inline code for complex addition/subtraction
 template <typename LLVMOP, typename OPTY>
-mlir::LLVM::InsertValueOp complexSum(OPTY sumop, mlir::ValueRange opnds,
-                                     mlir::ConversionPatternRewriter &rewriter,
-                                     fir::LLVMTypeConverter &lowering) {
+static mlir::LLVM::InsertValueOp
+complexSum(OPTY sumop, mlir::ValueRange opnds,
+           mlir::ConversionPatternRewriter &rewriter,
+           fir::LLVMTypeConverter &lowering) {
   mlir::Value a = opnds[0];
   mlir::Value b = opnds[1];
   auto loc = sumop.getLoc();
@@ -2216,6 +2333,7 @@
   return rewriter.create<mlir::LLVM::InsertValueOp>(loc, ty, r1, ry, c1);
 }
 
+namespace {
 struct AddcOpConversion : public FIROpConversion<fir::AddcOp> {
   using FIROpConversion::FIROpConversion;
 
@@ -2455,10 +2573,11 @@
     return success();
   }
 };
+} // namespace
 
 /// Construct an `llvm.extractvalue` instruction. It will return value at
 /// element \p x from  \p tuple.
-mlir::LLVM::ExtractValueOp
+static mlir::LLVM::ExtractValueOp
 genExtractValueWithIndex(mlir::Location loc, mlir::Value tuple, mlir::Type ty,
                          mlir::ConversionPatternRewriter &rewriter,
                          mlir::MLIRContext *ctx, int x) {
@@ -2467,6 +2586,7 @@
   return rewriter.create<mlir::LLVM::ExtractValueOp>(loc, xty, tuple, cx);
 }
 
+namespace {
 /// Convert `!fir.boxchar_len` to  `!llvm.extractvalue` for the 2nd part of the
 /// boxchar.
 struct BoxCharLenOpConversion : public FIROpConversion<fir::BoxCharLenOp> {
@@ -2598,25 +2718,26 @@
     mlir::OwningRewritePatternList pattern(context);
     pattern.insert<
         AbsentOpConversion, AddcOpConversion, AddrOfOpConversion,
-        AllocaOpConversion, BoxAddrOpConversion, BoxCharLenOpConversion,
-        BoxDimsOpConversion, BoxEleSizeOpConversion, BoxIsAllocOpConversion,
-        BoxIsArrayOpConversion, BoxIsPtrOpConversion, BoxProcHostOpConversion,
-        BoxRankOpConversion, BoxTypeDescOpConversion, CallOpConversion,
-        CmpcOpConversion, ConstcOpConversion, ConvertOpConversion,
-        DispatchOpConversion, DispatchTableOpConversion, DTEntryOpConversion,
-        DivcOpConversion, EmboxOpConversion, EmboxCharOpConversion,
-        EmboxProcOpConversion, ExtractValueOpConversion, FieldIndexOpConversion,
-        FirEndOpConversion, HasValueOpConversion, GenTypeDescOpConversion,
-        GlobalLenOpConversion, GlobalOpConversion, InsertOnRangeOpConversion,
-        InsertValueOpConversion, IsPresentOpConversion,
-        LenParamIndexOpConversion, LoadOpConversion, NegcOpConversion,
-        NoReassocOpConversion, MulcOpConversion, SelectCaseOpConversion,
-        SelectOpConversion, SelectRankOpConversion, SelectTypeOpConversion,
-        ShapeOpConversion, ShapeShiftOpConversion, ShiftOpConversion,
-        SliceOpConversion, StoreOpConversion, StringLitOpConversion,
-        SubcOpConversion, UnboxCharOpConversion, UnboxProcOpConversion,
-        UndefOpConversion, UnreachableOpConversion, XArrayCoorOpConversion,
-        XEmboxOpConversion, ZeroOpConversion>(typeConverter);
+        AllocaOpConversion, AllocMemOpConversion, BoxAddrOpConversion,
+        BoxCharLenOpConversion, BoxDimsOpConversion, BoxEleSizeOpConversion,
+        BoxIsAllocOpConversion, BoxIsArrayOpConversion, BoxIsPtrOpConversion,
+        BoxProcHostOpConversion, BoxRankOpConversion, BoxTypeDescOpConversion,
+        CallOpConversion, CmpcOpConversion, ConstcOpConversion,
+        ConvertOpConversion, DispatchOpConversion, DispatchTableOpConversion,
+        DTEntryOpConversion, DivcOpConversion, EmboxOpConversion,
+        EmboxCharOpConversion, EmboxProcOpConversion, ExtractValueOpConversion,
+        FieldIndexOpConversion, FirEndOpConversion, FreeMemOpConversion,
+        HasValueOpConversion, GenTypeDescOpConversion, GlobalLenOpConversion,
+        GlobalOpConversion, InsertOnRangeOpConversion, InsertValueOpConversion,
+        IsPresentOpConversion, LenParamIndexOpConversion, LoadOpConversion,
+        NegcOpConversion, NoReassocOpConversion, MulcOpConversion,
+        SelectCaseOpConversion, SelectOpConversion, SelectRankOpConversion,
+        SelectTypeOpConversion, ShapeOpConversion, ShapeShiftOpConversion,
+        ShiftOpConversion, SliceOpConversion, StoreOpConversion,
+        StringLitOpConversion, SubcOpConversion, UnboxCharOpConversion,
+        UnboxProcOpConversion, UndefOpConversion, UnreachableOpConversion,
+        XArrayCoorOpConversion, XEmboxOpConversion, ZeroOpConversion>(
+        typeConverter);
     mlir::populateStdToLLVMConversionPatterns(typeConverter, pattern);
     mlir::arith::populateArithmeticToLLVMConversionPatterns(typeConverter,
                                                             pattern);
Index: flang/test/Fir/Todo/allocmem.fir
===================================================================
--- /dev/null
+++ flang/test/Fir/Todo/allocmem.fir
@@ -0,0 +1,10 @@
+// RUN: %not_todo_cmd fir-opt --fir-to-llvm-ir="target=x86_64-unknown-linux-gnu" %s 2>&1 | FileCheck %s
+
+// Test `fir.allocmem` of derived type with LEN parameters conversion to llvm.
+// Not implemented yet.
+
+func @allocmem_test(%arg0 : i32, %arg1 : i16) {
+// CHECK: not yet implemented fir.allocmem codegen of derived type with length parameters
+  %0 = fir.allocmem !fir.type<_QTt(p1:i32,p2:i16){f1:i32,f2:f32}>(%arg0, %arg1 : i32, i16) {name = "_QEvar"}
+  return 
+}
Index: flang/test/Fir/convert-to-llvm.fir
===================================================================
--- flang/test/Fir/convert-to-llvm.fir
+++ flang/test/Fir/convert-to-llvm.fir
@@ -165,16 +165,55 @@
 
 // -----
 
-// Verify that fir.unreachable is transformed to llvm.unreachable
+// Verify that fir.allocmem is transformed to a call to malloc
+// and that fir.freemem is transformed to a call to free
+// Single item case
 
-// CHECK:  llvm.func @test_unreachable() {
-// CHECK-NEXT:    llvm.unreachable
-// CHECK-NEXT:  }
+func @test_alloc_and_freemem_one() {
+  %z0 = fir.allocmem i32
+  fir.freemem %z0 : !fir.heap<i32>
+  return
+}
+
+// CHECK-LABEL:  llvm.func @test_alloc_and_freemem_one() {
+// CHECK-NEXT:    [[N:%.*]] = llvm.mlir.constant(4 : i64) : i64
+// CHECK-NEXT:    llvm.call @malloc([[N]])
+// CHECK:         llvm.call @free(%{{.*}})
+// CHECK-NEXT:    llvm.return
+
+// -----
+// Verify that fir.allocmem is transformed to a call to malloc
+// and that fir.freemem is transformed to a call to free
+// Several item case
+
+func @test_alloc_and_freemem_several() {
+  %z0 = fir.allocmem !fir.array<100xf32>
+  fir.freemem %z0 : !fir.heap<!fir.array<100xf32>>
+  return
+}
+
+// CHECK-LABEL:  llvm.func @test_alloc_and_freemem_several() {
+// CHECK: [[NULL:%.*]]  = llvm.mlir.null : !llvm.ptr<array<100 x f32>>
+// CHECK: [[PTR:%.*]]  = llvm.getelementptr [[NULL]][{{.*}}] : (!llvm.ptr<array<100 x f32>>, i64) -> !llvm.ptr<array<100 x f32>>
+// CHECK: [[N:%.*]]  = llvm.ptrtoint [[PTR]] : !llvm.ptr<array<100 x f32>> to i64
+// CHECK: [[MALLOC:%.*]] = llvm.call @malloc([[N]])
+// CHECK: [[B1:%.*]] = llvm.bitcast [[MALLOC]] : !llvm.ptr<i8> to !llvm.ptr<array<100 x f32>>
+// CHECK: [[B2:%.*]] = llvm.bitcast [[B1]] : !llvm.ptr<array<100 x f32>> to !llvm.ptr<i8>
+// CHECK:              llvm.call @free([[B2]])
+// CHECK:              llvm.return
+
+// -----
+
+// Verify that fir.unreachable is transformed to llvm.unreachable
 
 func @test_unreachable() {
   fir.unreachable
 }
 
+// CHECK:  llvm.func @test_unreachable() {
+// CHECK-NEXT:    llvm.unreachable
+// CHECK-NEXT:  }
+
 // -----
 
 // Test `fir.select` operation conversion pattern.