feat: add propagateForallPropDown

fix: bug in propagateImpliesDown
term has not been internalized
2026-04-05 03:34:08 +00:00 · 2025-01-08 09:40:35 -08:00 · 2025-01-08 09:18:14 -08:00 · 2025-01-08 08:23:56 -08:00
263 changed files with 1360 additions and 8166 deletions
--- a/.github/workflows/ci.yml
+++ b/.github/workflows/ci.yml
@@ -238,7 +238,7 @@ jobs:
                "name": "Linux 32bit",
                "os": "ubuntu-latest",
                // Use 32bit on stage0 and stage1 to keep oleans compatible
-                "CMAKE_OPTIONS": "-DSTAGE0_USE_GMP=OFF -DSTAGE0_LEAN_EXTRA_CXX_FLAGS='-m32' -DSTAGE0_LEANC_OPTS='-m32' -DSTAGE0_MMAP=OFF -DUSE_GMP=OFF -DLEAN_EXTRA_CXX_FLAGS='-m32' -DLEANC_OPTS='-m32' -DMMAP=OFF -DLEAN_INSTALL_SUFFIX=-linux_x86 -DCMAKE_LIBRARY_PATH=/usr/lib/i386-linux-gnu/ -DSTAGE0_CMAKE_LIBRARY_PATH=/usr/lib/i386-linux-gnu/ -DPKG_CONFIG_EXECUTABLE=/usr/bin/i386-linux-gnu-pkg-config",
+                "CMAKE_OPTIONS": "-DSTAGE0_USE_GMP=OFF -DSTAGE0_LEAN_EXTRA_CXX_FLAGS='-m32' -DSTAGE0_LEANC_OPTS='-m32' -DSTAGE0_MMAP=OFF -DUSE_GMP=OFF -DLEAN_EXTRA_CXX_FLAGS='-m32' -DLEANC_OPTS='-m32' -DMMAP=OFF -DLEAN_INSTALL_SUFFIX=-linux_x86 -DCMAKE_LIBRARY_PATH=/usr/lib/i386-linux-gnu/ -DSTAGE0_CMAKE_LIBRARY_PATH=/usr/lib/i386-linux-gnu/",
                "cmultilib": true,
                "release": true,
                "check-level": 2,
@@ -327,7 +327,7 @@ jobs:
        run: |
          sudo dpkg --add-architecture i386
          sudo apt-get update
-          sudo apt-get install -y gcc-multilib g++-multilib ccache libuv1-dev:i386 pkgconf:i386
+          sudo apt-get install -y gcc-multilib g++-multilib ccache libuv1-dev:i386
        if: matrix.cmultilib
      - name: Cache
        uses: actions/cache@v4
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@@ -18,9 +18,6 @@ foreach(var ${vars})
    if("${var}" MATCHES "LLVM*")
      list(APPEND STAGE0_ARGS "-D${var}=${${var}}")
    endif()
-    if("${var}" MATCHES "PKG_CONFIG*")
-      list(APPEND STAGE0_ARGS "-D${var}=${${var}}")
-    endif()
  elseif(("${var}" MATCHES "CMAKE_.*") AND NOT ("${var}" MATCHES "CMAKE_BUILD_TYPE") AND NOT ("${var}" MATCHES "CMAKE_HOME_DIRECTORY"))
    list(APPEND PLATFORM_ARGS "-D${var}=${${var}}")
  endif()
--- a/doc/dev/commit_convention.md
+++ b/doc/dev/commit_convention.md
@@ -33,9 +33,6 @@ Format of the commit message
 - chore (maintain, ex: travis-ci)
 - perf (performance improvement, optimization, ...)

-Every `feat` or `fix` commit must have a `changelog-*` label, and a commit message
-beginning with "This PR " that will be included in the changelog.
-
 ``<subject>`` has the following constraints:

 - use imperative, present tense: "change" not "changed" nor "changes"
@@ -47,7 +44,6 @@ beginning with "This PR " that will be included in the changelog.
 - just as in ``<subject>``, use imperative, present tense
 - includes motivation for the change and contrasts with previous
   behavior
- - If a `changelog-*` label is present, the body must begin with "This PR ".

 ``<footer>`` is optional and may contain two items:

@@ -64,21 +60,17 @@ Examples

 fix: add declarations for operator<<(std::ostream&, expr const&) and operator<<(std::ostream&, context const&) in the kernel

-This PR adds declarations `operator<<` for raw printing.
 The actual implementation of these two operators is outside of the
-kernel. They are implemented in the file 'library/printer.cpp'.
-
-We declare them in the kernel to prevent the following problem.
-Suppose there is a file 'foo.cpp' that does not include 'library/printer.h',
+kernel. They are implemented in the file 'library/printer.cpp'. We
+declare them in the kernel to prevent the following problem. Suppose
+there is a file 'foo.cpp' that does not include 'library/printer.h',
 but contains
-```cpp
-expr a;
-...
-std::cout << a << "\n";
-...
-```
+
+    expr a;
+    ...
+    std::cout << a << "\n";
+    ...

 The compiler does not generate an error message. It silently uses the
 operator bool() to coerce the expression into a Boolean. This produces
 counter-intuitive behavior, and may confuse developers.
-
--- a/doc/dev/ffi.md
+++ b/doc/dev/ffi.md
@@ -49,9 +49,8 @@ In the case of `@[extern]` all *irrelevant* types are removed first; see next se
  is represented by the representation of that parameter's type.

  For example, `{ x : α // p }`, the `Subtype` structure of a value of type `α` and an irrelevant proof, is represented by the representation of `α`.
-  Similarly, the signed integer types `Int8`, ..., `Int64`, `ISize` are also represented by the unsigned C types `uint8_t`, ..., `uint64_t`, `size_t`, respectively, because they have a trivial structure.
-* `Nat` and `Int` are represented by `lean_object *`.
-  Their runtime values is either a pointer to an opaque bignum object or, if the lowest bit of the "pointer" is 1 (`lean_is_scalar`), an encoded unboxed natural number or integer (`lean_box`/`lean_unbox`).
+* `Nat` is represented by `lean_object *`.
+  Its runtime value is either a pointer to an opaque bignum object or, if the lowest bit of the "pointer" is 1 (`lean_is_scalar`), an encoded unboxed natural number (`lean_box`/`lean_unbox`).
 * A universe `Sort u`, type constructor `... → Sort u`, or proposition `p : Prop` is *irrelevant* and is either statically erased (see above) or represented as a `lean_object *` with the runtime value `lean_box(0)`
 * Any other type is represented by `lean_object *`.
  Its runtime value is a pointer to an object of a subtype of `lean_object` (see the "Inductive types" section below) or the unboxed value `lean_box(cidx)` for the `cidx`th constructor of an inductive type if this constructor does not have any relevant parameters.
--- a/doc/dev/index.md
+++ b/doc/dev/index.md
@@ -80,10 +80,3 @@ Unlike most Lean projects, all submodules of the `Lean` module begin with the
 `prelude` keyword. This disables the automated import of `Init`, meaning that
 developers need to figure out their own subset of `Init` to import. This is done
 such that changing files in `Init` doesn't force a full rebuild of `Lean`.
-
-### Testing against Mathlib/Batteries
-You can test a Lean PR against Mathlib and Batteries by rebasing your PR
-on to `nightly-with-mathlib` branch. (It is fine to force push after rebasing.)
-CI will generate a branch of Mathlib and Batteries called `lean-pr-testing-NNNN`
-that uses the toolchain for your PR, and will report back to the Lean PR with results from Mathlib CI.
-See https://leanprover-community.github.io/contribute/tags_and_branches.html for more details.
--- a/doc/dev/release_checklist.md
+++ b/doc/dev/release_checklist.md
@@ -37,32 +37,16 @@ We'll use `v4.6.0` as the intended release version as a running example.
    - Create the tag `v4.6.0` from `master`/`main` and push it.
    - Merge the tag `v4.6.0` into the `stable` branch and push it.
  - We do this for the repositories:
-    - [Batteries](https://github.com/leanprover-community/batteries)
-      - No dependencies
-      - Toolchain bump PR
-      - Create and push the tag
-      - Merge the tag into `stable`
    - [lean4checker](https://github.com/leanprover/lean4checker)
      - No dependencies
      - Toolchain bump PR
      - Create and push the tag
      - Merge the tag into `stable`
-    - [doc-gen4](https://github.com/leanprover/doc-gen4)
-      - Dependencies: exist, but they're not part of the release workflow
-      - Toolchain bump PR including updated Lake manifest
-      - Create and push the tag
-      - There is no `stable` branch; skip this step
-    - [Verso](https://github.com/leanprover/verso)
-      - Dependencies: exist, but they're not part of the release workflow
-      - The `SubVerso` dependency should be compatible with _every_ Lean release simultaneously, rather than following this workflow
-      - Toolchain bump PR including updated Lake manifest
-      - Create and push the tag
-      - There is no `stable` branch; skip this step
-    - [Cli](https://github.com/leanprover/lean4-cli)
+    - [Batteries](https://github.com/leanprover-community/batteries)
      - No dependencies
      - Toolchain bump PR
      - Create and push the tag
-      - There is no `stable` branch; skip this step
+      - Merge the tag into `stable`
    - [ProofWidgets4](https://github.com/leanprover-community/ProofWidgets4)
      - Dependencies: `Batteries`
      - Note on versions and branches:
@@ -77,6 +61,17 @@ We'll use `v4.6.0` as the intended release version as a running example.
      - Toolchain bump PR including updated Lake manifest
      - Create and push the tag
      - Merge the tag into `stable`
+    - [doc-gen4](https://github.com/leanprover/doc-gen4)
+      - Dependencies: exist, but they're not part of the release workflow
+      - Toolchain bump PR including updated Lake manifest
+      - Create and push the tag
+      - There is no `stable` branch; skip this step
+    - [Verso](https://github.com/leanprover/verso)
+      - Dependencies: exist, but they're not part of the release workflow
+      - The `SubVerso` dependency should be compatible with _every_ Lean release simultaneously, rather than following this workflow
+      - Toolchain bump PR including updated Lake manifest
+      - Create and push the tag
+      - There is no `stable` branch; skip this step
    - [import-graph](https://github.com/leanprover-community/import-graph)
      - Toolchain bump PR including updated Lake manifest
      - Create and push the tag
--- a/doc/make/osx-10.9.md
+++ b/doc/make/osx-10.9.md
@@ -32,13 +32,12 @@ following to use `g++`.
 cmake -DCMAKE_CXX_COMPILER=g++ ...
 ```

-## Required Packages: CMake, GMP, libuv, pkgconf
+## Required Packages: CMake, GMP, libuv

 ```bash
 brew install cmake
 brew install gmp
 brew install libuv
-brew install pkgconf
 ```

 ## Recommended Packages: CCache
--- a/flake.nix
+++ b/flake.nix
@@ -28,7 +28,7 @@
          stdenv = pkgs.overrideCC pkgs.stdenv lean-packages.llvmPackages.clang;
        } ({
          buildInputs = with pkgs; [
-            cmake gmp libuv ccache cadical pkg-config
+            cmake gmp libuv ccache cadical
            lean-packages.llvmPackages.llvm  # llvm-symbolizer for asan/lsan
            gdb
            tree  # for CI
--- a/nix/bootstrap.nix
+++ b/nix/bootstrap.nix
@@ -1,12 +1,12 @@
 { src, debug ? false, stage0debug ? false, extraCMakeFlags ? [],
-  stdenv, lib, cmake, pkg-config, gmp, libuv, cadical, git, gnumake, bash, buildLeanPackage, writeShellScriptBin, runCommand, symlinkJoin, lndir, perl, gnused, darwin, llvmPackages, linkFarmFromDrvs,
+  stdenv, lib, cmake, gmp, libuv, cadical, git, gnumake, bash, buildLeanPackage, writeShellScriptBin, runCommand, symlinkJoin, lndir, perl, gnused, darwin, llvmPackages, linkFarmFromDrvs,
  ... } @ args:
 with builtins;
 lib.warn "The Nix-based build is deprecated" rec {
  inherit stdenv;
  sourceByRegex = p: rs: lib.sourceByRegex p (map (r: "(/src/)?${r}") rs);
  buildCMake = args: stdenv.mkDerivation ({
-    nativeBuildInputs = [ cmake pkg-config ];
+    nativeBuildInputs = [ cmake ];
    buildInputs = [ gmp libuv llvmPackages.llvm ];
    # https://github.com/NixOS/nixpkgs/issues/60919
    hardeningDisable = [ "all" ];
--- a/script/push_repo_release_tag.py
+++ b/script/push_repo_release_tag.py
@@ -1,69 +0,0 @@
-#!/usr/bin/env python3
-import sys
-import subprocess
-import requests
-
-def main():
-    if len(sys.argv) != 4:
-        print("Usage: ./push_repo_release_tag.py <repo> <branch> <version_tag>")
-        sys.exit(1)
-
-    repo, branch, version_tag = sys.argv[1], sys.argv[2], sys.argv[3]
-
-    if branch not in {"master", "main"}:
-        print(f"Error: Branch '{branch}' is not 'master' or 'main'.")
-        sys.exit(1)
-
-    # Get the `lean-toolchain` file content
-    lean_toolchain_url = f"https://raw.githubusercontent.com/{repo}/{branch}/lean-toolchain"
-    try:
-        response = requests.get(lean_toolchain_url)
-        response.raise_for_status()
-    except requests.exceptions.RequestException as e:
-        print(f"Error fetching 'lean-toolchain' file: {e}")
-        sys.exit(1)
-
-    lean_toolchain_content = response.text.strip()
-    expected_prefix = "leanprover/lean4:"
-    if not lean_toolchain_content.startswith(expected_prefix) or lean_toolchain_content != f"{expected_prefix}{version_tag}":
-        print(f"Error: 'lean-toolchain' content does not match '{expected_prefix}{version_tag}'.")
-        sys.exit(1)
-
-    # Create and push the tag using `gh`
-    try:
-        # Check if the tag already exists
-        list_tags_cmd = ["gh", "api", f"repos/{repo}/git/matching-refs/tags/v4", "--jq", ".[].ref"]
-        list_tags_output = subprocess.run(list_tags_cmd, capture_output=True, text=True)
-
-        if list_tags_output.returncode == 0:
-            existing_tags = list_tags_output.stdout.strip().splitlines()
-            if f"refs/tags/{version_tag}" in existing_tags:
-                print(f"Error: Tag '{version_tag}' already exists.")
-                print("Existing tags starting with 'v4':")
-                for tag in existing_tags:
-                    print(tag.replace("refs/tags/", ""))
-                sys.exit(1)
-
-        # Get the SHA of the branch
-        get_sha_cmd = [
-            "gh", "api", f"repos/{repo}/git/ref/heads/{branch}", "--jq", ".object.sha"
-        ]
-        sha_result = subprocess.run(get_sha_cmd, capture_output=True, text=True, check=True)
-        sha = sha_result.stdout.strip()
-
-        # Create the tag
-        create_tag_cmd = [
-            "gh", "api", f"repos/{repo}/git/refs",
-            "-X", "POST",
-            "-F", f"ref=refs/tags/{version_tag}",
-            "-F", f"sha={sha}"
-        ]
-        subprocess.run(create_tag_cmd, capture_output=True, text=True, check=True)
-
-        print(f"Successfully created and pushed tag '{version_tag}' to {repo}.")
-    except subprocess.CalledProcessError as e:
-        print(f"Error while creating/pushing tag: {e.stderr.strip() if e.stderr else e}")
-        sys.exit(1)
-
-if __name__ == "__main__":
-    main()
--- a/script/release_checklist.py
+++ b/script/release_checklist.py
@@ -22,36 +22,6 @@ def get_github_token():
        print("Warning: 'gh' CLI not found. Some API calls may be rate-limited.")
    return None

-def strip_rc_suffix(toolchain):
-    """Remove -rcX suffix from the toolchain."""
-    return toolchain.split("-")[0]
-
-def branch_exists(repo_url, branch, github_token):
-    api_url = repo_url.replace("https://github.com/", "https://api.github.com/repos/") + f"/branches/{branch}"
-    headers = {'Authorization': f'token {github_token}'} if github_token else {}
-    response = requests.get(api_url, headers=headers)
-    return response.status_code == 200
-
-def tag_exists(repo_url, tag_name, github_token):
-    api_url = repo_url.replace("https://github.com/", "https://api.github.com/repos/") + f"/git/refs/tags/{tag_name}"
-    headers = {'Authorization': f'token {github_token}'} if github_token else {}
-    response = requests.get(api_url, headers=headers)
-    return response.status_code == 200
-
-def release_page_exists(repo_url, tag_name, github_token):
-    api_url = repo_url.replace("https://github.com/", "https://api.github.com/repos/") + f"/releases/tags/{tag_name}"
-    headers = {'Authorization': f'token {github_token}'} if github_token else {}
-    response = requests.get(api_url, headers=headers)
-    return response.status_code == 200
-
-def get_release_notes(repo_url, tag_name, github_token):
-    api_url = repo_url.replace("https://github.com/", "https://api.github.com/repos/") + f"/releases/tags/{tag_name}"
-    headers = {'Authorization': f'token {github_token}'} if github_token else {}
-    response = requests.get(api_url, headers=headers)
-    if response.status_code == 200:
-        return response.json().get("body", "").strip()
-    return None
-
 def get_branch_content(repo_url, branch, file_path, github_token):
    api_url = repo_url.replace("https://github.com/", "https://api.github.com/repos/") + f"/contents/{file_path}?ref={branch}"
    headers = {'Authorization': f'token {github_token}'} if github_token else {}
@@ -65,20 +35,11 @@ def get_branch_content(repo_url, branch, file_path, github_token):
            return None
    return None

-def parse_version(version_str):
-    # Remove 'v' prefix and extract version and release candidate suffix
-    if ':' in version_str:
-        version_str = version_str.split(':')[1]
-    version = version_str.lstrip('v')
-    parts = version.split('-')
-    base_version = tuple(map(int, parts[0].split('.')))
-    rc_part = parts[1] if len(parts) > 1 and parts[1].startswith('rc') else None
-    rc_number = int(rc_part[2:]) if rc_part else float('inf')  # Treat non-rc as higher than rc
-    return base_version + (rc_number,)
-
-def is_version_gte(version1, version2):
-    """Check if version1 >= version2, including proper handling of release candidates."""
-    return parse_version(version1) >= parse_version(version2)
+def tag_exists(repo_url, tag_name, github_token):
+    api_url = repo_url.replace("https://github.com/", "https://api.github.com/repos/") + f"/git/refs/tags/{tag_name}"
+    headers = {'Authorization': f'token {github_token}'} if github_token else {}
+    response = requests.get(api_url, headers=headers)
+    return response.status_code == 200

 def is_merged_into_stable(repo_url, tag_name, stable_branch, github_token):
    # First get the commit SHA for the tag
@@ -103,38 +64,23 @@ def is_merged_into_stable(repo_url, tag_name, stable_branch, github_token):
    stable_commits = [commit['sha'] for commit in commits_response.json()]
    return tag_sha in stable_commits

+def parse_version(version_str):
+    # Remove 'v' prefix and split into components
+    # Handle Lean toolchain format (leanprover/lean4:v4.x.y)
+    if ':' in version_str:
+        version_str = version_str.split(':')[1]
+    version = version_str.lstrip('v')
+    # Handle release candidates by removing -rc part for comparison
+    version = version.split('-')[0]
+    return tuple(map(int, version.split('.')))
+
+def is_version_gte(version1, version2):
+    """Check if version1 >= version2"""
+    return parse_version(version1) >= parse_version(version2)
+
 def is_release_candidate(version):
    return "-rc" in version

-def check_cmake_version(repo_url, branch, version_major, version_minor, github_token):
-    """Verify the CMake version settings in src/CMakeLists.txt."""
-    cmake_file_path = "src/CMakeLists.txt"
-    content = get_branch_content(repo_url, branch, cmake_file_path, github_token)
-    if content is None:
-        print(f"  ❌ Could not retrieve {cmake_file_path} from {branch}")
-        return False
-
-    expected_lines = [
-        f"set(LEAN_VERSION_MAJOR {version_major})",
-        f"set(LEAN_VERSION_MINOR {version_minor})",
-        f"set(LEAN_VERSION_PATCH 0)",
-        f"set(LEAN_VERSION_IS_RELEASE 1)"
-    ]
-
-    for line in expected_lines:
-        if not any(l.strip().startswith(line) for l in content.splitlines()):
-            print(f"  ❌ Missing or incorrect line in {cmake_file_path}: {line}")
-            return False
-
-    print(f"  ✅ CMake version settings are correct in {cmake_file_path}")
-    return True
-
-def extract_org_repo_from_url(repo_url):
-    """Extract the 'org/repo' part from a GitHub URL."""
-    if repo_url.startswith("https://github.com/"):
-        return repo_url.replace("https://github.com/", "").rstrip("/")
-    return repo_url
-
 def main():
    github_token = get_github_token()

@@ -143,47 +89,6 @@ def main():
        sys.exit(1)

    toolchain = sys.argv[1]
-    stripped_toolchain = strip_rc_suffix(toolchain)
-    lean_repo_url = "https://github.com/leanprover/lean4"
-
-    # Preliminary checks
-    print("\nPerforming preliminary checks...")
-
-    # Check for branch releases/v4.Y.0
-    version_major, version_minor, _ = map(int, stripped_toolchain.lstrip('v').split('.'))
-    branch_name = f"releases/v{version_major}.{version_minor}.0"
-    if branch_exists(lean_repo_url, branch_name, github_token):
-        print(f"  ✅ Branch {branch_name} exists")
-
-        # Check CMake version settings
-        check_cmake_version(lean_repo_url, branch_name, version_major, version_minor, github_token)
-    else:
-        print(f"  ❌ Branch {branch_name} does not exist")
-
-    # Check for tag v4.X.Y(-rcZ)
-    if tag_exists(lean_repo_url, toolchain, github_token):
-        print(f"  ✅ Tag {toolchain} exists")
-    else:
-        print(f"  ❌ Tag {toolchain} does not exist.")
-
-    # Check for release page
-    if release_page_exists(lean_repo_url, toolchain, github_token):
-        print(f"  ✅ Release page for {toolchain} exists")
-
-        # Check the first line of the release notes
-        release_notes = get_release_notes(lean_repo_url, toolchain, github_token)
-        if release_notes and release_notes.splitlines()[0].strip() == toolchain:
-            print(f"  ✅ Release notes look good.")
-        else:
-            previous_minor_version = version_minor - 1
-            previous_stable_branch = f"releases/v{version_major}.{previous_minor_version}.0"
-            previous_release = f"v{version_major}.{previous_minor_version}.0"
-            print(f"  ❌ Release notes not published. Please run `script/release_notes.py {previous_release}` on branch `{previous_stable_branch}`.")
-    else:
-        print(f"  ❌ Release page for {toolchain} does not exist")
-
-    # Load repositories and perform further checks
-    print("\nChecking repositories...")

    with open(os.path.join(os.path.dirname(__file__), "release_repos.yml")) as f:
        repos = yaml.safe_load(f)["repositories"]
@@ -212,7 +117,7 @@ def main():
        # Only check for tag if toolchain-tag is true
        if check_tag:
            if not tag_exists(url, toolchain, github_token):
-                print(f"  ❌ Tag {toolchain} does not exist. Run `script/push_repo_release_tag.py {extract_org_repo_from_url(url)} {branch} {toolchain}`.")
+                print(f"  ❌ Tag {toolchain} does not exist")
                continue
            print(f"  ✅ Tag {toolchain} exists")

--- a/script/release_repos.yml
+++ b/script/release_repos.yml
@@ -27,13 +27,6 @@ repositories:
    branch: main
    dependencies: []

-  - name: Cli
-    url: https://github.com/leanprover/lean4-cli
-    toolchain-tag: true
-    stable-branch: false
-    branch: main
-    dependencies: []
-
  - name: ProofWidgets4
    url: https://github.com/leanprover-community/ProofWidgets4
    toolchain-tag: false
--- a/src/CMakeLists.txt
+++ b/src/CMakeLists.txt
@@ -295,15 +295,14 @@ index 5e8e0166..f3b29134 100644
 	  PATCH_COMMAND git reset --hard HEAD && printf "${LIBUV_PATCH}" > patch.diff && git apply patch.diff
    BUILD_IN_SOURCE ON
    INSTALL_COMMAND "")
-  set(LIBUV_INCLUDE_DIRS "${CMAKE_BINARY_DIR}/libuv/src/libuv/include")
-  set(LIBUV_LDFLAGS "${CMAKE_BINARY_DIR}/libuv/src/libuv/libuv.a")
+  set(LIBUV_INCLUDE_DIR "${CMAKE_BINARY_DIR}/libuv/src/libuv/include")
+  set(LIBUV_LIBRARIES "${CMAKE_BINARY_DIR}/libuv/src/libuv/libuv.a")
 else()
  find_package(LibUV 1.0.0 REQUIRED)
 endif()
-include_directories(${LIBUV_INCLUDE_DIRS})
+include_directories(${LIBUV_INCLUDE_DIR})
 if(NOT LEAN_STANDALONE)
-  string(JOIN " " LIBUV_LDFLAGS ${LIBUV_LDFLAGS})
-  string(APPEND LEAN_EXTRA_LINKER_FLAGS " ${LIBUV_LDFLAGS}")
+  string(APPEND LEAN_EXTRA_LINKER_FLAGS " ${LIBUV_LIBRARIES}")
 endif()

 # Windows SDK (for ICU)
--- a/src/Init/Conv.lean
+++ b/src/Init/Conv.lean
@@ -150,10 +150,6 @@ See the `simp` tactic for more information. -/
 syntax (name := simp) "simp" optConfig (discharger)? (&" only")?
  (" [" withoutPosition((simpStar <|> simpErase <|> simpLemma),*) "]")? : conv

-/-- `simp?` takes the same arguments as `simp`, but reports an equivalent call to `simp only`
-that would be sufficient to close the goal. See the `simp?` tactic for more information. -/
-syntax (name := simpTrace) "simp?" optConfig (discharger)? (&" only")? (simpArgs)? : conv
-
 /--
 `dsimp` is the definitional simplifier in `conv`-mode. It differs from `simp` in that it only
 applies theorems that hold by reflexivity.
@@ -171,9 +167,6 @@ example (a : Nat): (0 + 0) = a - a := by
 syntax (name := dsimp) "dsimp" optConfig (discharger)? (&" only")?
  (" [" withoutPosition((simpErase <|> simpLemma),*) "]")? : conv

-@[inherit_doc simpTrace]
-syntax (name := dsimpTrace) "dsimp?" optConfig (&" only")? (dsimpArgs)? : conv
-
 /-- `simp_match` simplifies match expressions. For example,
 ```
 match [a, b] with
--- a/src/Init/Data/Array/Basic.lean
+++ b/src/Init/Data/Array/Basic.lean
@@ -244,7 +244,8 @@ def ofFn {n} (f : Fin n → α) : Array α := go 0 (mkEmpty n) where
 def range (n : Nat) : Array Nat :=
  ofFn fun (i : Fin n) => i

-@[inline] protected def singleton (v : α) : Array α := #[v]
+def singleton (v : α) : Array α :=
+  mkArray 1 v

 def back! [Inhabited α] (a : Array α) : α :=
  a[a.size - 1]!
@@ -576,12 +577,6 @@ def foldl {α : Type u} {β : Type v} (f : β → α → β) (init : β) (as : A
 def foldr {α : Type u} {β : Type v} (f : α → β → β) (init : β) (as : Array α) (start := as.size) (stop := 0) : β :=
  Id.run <| as.foldrM f init start stop

-/-- Sum of an array.
-
-`Array.sum #[a, b, c] = a + (b + (c + 0))` -/
-def sum {α} [Add α] [Zero α] : Array α → α :=
-  foldr (· + ·) 0
-
@[inline]
 def map {α : Type u} {β : Type v} (f : α → β) (as : Array α) : Array β :=
  Id.run <| as.mapM f
--- a/src/Init/Data/Array/Bootstrap.lean
+++ b/src/Init/Data/Array/Bootstrap.lean
@@ -81,18 +81,12 @@ theorem foldrM_eq_reverse_foldlM_toList [Monad m] (f : α → β → m β) (init

@[simp] theorem toList_empty : (#[] : Array α).toList = [] := rfl

-@[simp] theorem append_empty (as : Array α) : as ++ #[] = as := by
+@[simp] theorem append_nil (as : Array α) : as ++ #[] = as := by
  apply ext'; simp only [toList_append, toList_empty, List.append_nil]

-@[deprecated append_empty (since := "2025-01-13")]
-abbrev append_nil := @append_empty
-
-@[simp] theorem empty_append (as : Array α) : #[] ++ as = as := by
+@[simp] theorem nil_append (as : Array α) : #[] ++ as = as := by
  apply ext'; simp only [toList_append, toList_empty, List.nil_append]

-@[deprecated empty_append (since := "2025-01-13")]
-abbrev nil_append := @empty_append
-
@[simp] theorem append_assoc (as bs cs : Array α) : as ++ bs ++ cs = as ++ (bs ++ cs) := by
  apply ext'; simp only [toList_append, List.append_assoc]

--- a/src/Init/Data/Array/Find.lean
+++ b/src/Init/Data/Array/Find.lean
@@ -74,12 +74,12 @@ theorem findSome?_append {l₁ l₂ : Array α} : (l₁ ++ l₂).findSome? f = (

 theorem getElem?_zero_flatten (L : Array (Array α)) :
    (flatten L)[0]? = L.findSome? fun l => l[0]? := by
-  cases L using array₂_induction
+  cases L using array_array_induction
  simp [← List.head?_eq_getElem?, List.head?_flatten, List.findSome?_map, Function.comp_def]

 theorem getElem_zero_flatten.proof {L : Array (Array α)} (h : 0 < L.flatten.size) :
    (L.findSome? fun l => l[0]?).isSome := by
-  cases L using array₂_induction
+  cases L using array_array_induction
  simp only [List.findSome?_toArray, List.findSome?_map, Function.comp_def, List.getElem?_toArray,
    List.findSome?_isSome_iff, isSome_getElem?]
  simp only [flatten_toArray_map_toArray, size_toArray, List.length_flatten,
@@ -95,7 +95,7 @@ theorem getElem_zero_flatten {L : Array (Array α)} (h) :

 theorem back?_flatten {L : Array (Array α)} :
    (flatten L).back? = (L.findSomeRev? fun l => l.back?) := by
-  cases L using array₂_induction
+  cases L using array_array_induction
  simp [List.getLast?_flatten, ← List.map_reverse, List.findSome?_map, Function.comp_def]

 theorem findSome?_mkArray : findSome? f (mkArray n a) = if n = 0 then none else f a := by
@@ -203,7 +203,7 @@ theorem get_find?_mem {xs : Array α} (h) : (xs.find? p).get h ∈ xs := by

@[simp] theorem find?_flatten (xs : Array (Array α)) (p : α → Bool) :
    xs.flatten.find? p = xs.findSome? (·.find? p) := by
-  cases xs using array₂_induction
+  cases xs using array_array_induction
  simp [List.findSome?_map, Function.comp_def]

 theorem find?_flatten_eq_none {xs : Array (Array α)} {p : α → Bool} :
@@ -220,7 +220,7 @@ theorem find?_flatten_eq_some {xs : Array (Array α)} {p : α → Bool} {a : α}
      p a ∧ ∃ (as : Array (Array α)) (ys zs : Array α) (bs : Array (Array α)),
        xs = as.push (ys.push a ++ zs) ++ bs ∧
        (∀ a ∈ as, ∀ x ∈ a, !p x) ∧ (∀ x ∈ ys, !p x) := by
-  cases xs using array₂_induction
+  cases xs using array_array_induction
  simp only [flatten_toArray_map_toArray, List.find?_toArray, List.find?_flatten_eq_some]
  simp only [Bool.not_eq_eq_eq_not, Bool.not_true, exists_and_right, and_congr_right_iff]
  intro w
--- a/src/Init/Data/Array/Lemmas.lean
+++ b/src/Init/Data/Array/Lemmas.lean
--- a/src/Init/Data/BitVec/Lemmas.lean
+++ b/src/Init/Data/BitVec/Lemmas.lean
@@ -9,9 +9,7 @@ import Init.Data.Bool
 import Init.Data.BitVec.Basic
 import Init.Data.Fin.Lemmas
 import Init.Data.Nat.Lemmas
-import Init.Data.Nat.Div.Lemmas
 import Init.Data.Nat.Mod
-import Init.Data.Nat.Div.Lemmas
 import Init.Data.Int.Bitwise.Lemmas
 import Init.Data.Int.Pow

@@ -100,12 +98,6 @@ theorem ofFin_eq_ofNat : @BitVec.ofFin w (Fin.mk x lt) = BitVec.ofNat w x := by
 theorem eq_of_toNat_eq {n} : ∀ {x y : BitVec n}, x.toNat = y.toNat → x = y
  | ⟨_, _⟩, ⟨_, _⟩, rfl => rfl

-/-- Prove nonequality of bitvectors in terms of nat operations. -/
-theorem toNat_ne_iff_ne {n} {x y : BitVec n} : x.toNat ≠ y.toNat ↔ x ≠ y := by
-  constructor
-  · rintro h rfl; apply h rfl
-  · intro h h_eq; apply h <| eq_of_toNat_eq h_eq
-
@[simp] theorem val_toFin (x : BitVec w) : x.toFin.val = x.toNat := rfl

@[bv_toNat] theorem toNat_eq {x y : BitVec n} : x = y ↔ x.toNat = y.toNat :=
@@ -450,10 +442,6 @@ theorem toInt_eq_toNat_cond (x : BitVec n) :
        (x.toNat : Int) - (2^n : Nat) :=
  rfl

-theorem toInt_eq_toNat_of_lt {x : BitVec n} (h : 2 * x.toNat < 2^n) :
-    x.toInt = x.toNat := by
-  simp [toInt_eq_toNat_cond, h]
-
 theorem msb_eq_false_iff_two_mul_lt {x : BitVec w} : x.msb = false ↔ 2 * x.toNat < 2^w := by
  cases w <;> simp [Nat.pow_succ, Nat.mul_comm _ 2, msb_eq_decide, toNat_of_zero_length]

@@ -466,9 +454,6 @@ theorem toInt_eq_msb_cond (x : BitVec w) :
  simp only [BitVec.toInt, ← msb_eq_false_iff_two_mul_lt]
  cases x.msb <;> rfl

-theorem toInt_eq_toNat_of_msb {x : BitVec w} (h : x.msb = false) :
-    x.toInt = x.toNat := by
-  simp [toInt_eq_msb_cond, h]

 theorem toInt_eq_toNat_bmod (x : BitVec n) : x.toInt = Int.bmod x.toNat (2^n) := by
  simp only [toInt_eq_toNat_cond]
@@ -2315,12 +2300,6 @@ theorem ofNat_sub_ofNat {n} (x y : Nat) : BitVec.ofNat n x - BitVec.ofNat n y =
@[simp, bv_toNat] theorem toNat_neg (x : BitVec n) : (- x).toNat = (2^n - x.toNat) % 2^n := by
  simp [Neg.neg, BitVec.neg]

-theorem toNat_neg_of_pos {x : BitVec n} (h : 0#n < x) :
-    (- x).toNat = 2^n - x.toNat := by
-  change 0 < x.toNat at h
-  rw [toNat_neg, Nat.mod_eq_of_lt]
-  omega
-
 theorem toInt_neg {x : BitVec w} :
    (-x).toInt = (-x.toInt).bmod (2 ^ w) := by
  rw [← BitVec.zero_sub, toInt_sub]
@@ -2607,13 +2586,13 @@ theorem udiv_def {x y : BitVec n} : x / y = BitVec.ofNat n (x.toNat / y.toNat) :
  rw [← udiv_eq]
  simp [udiv, bv_toNat, h, Nat.mod_eq_of_lt]

-@[simp]
-theorem toFin_udiv {x y : BitVec n} : (x / y).toFin = x.toFin / y.toFin := by
-  rfl
-
@[simp, bv_toNat]
 theorem toNat_udiv {x y : BitVec n} : (x / y).toNat = x.toNat / y.toNat := by
-  rfl
+  rw [udiv_def]
+  by_cases h : y = 0
+  · simp [h]
+  · rw [toNat_ofNat, Nat.mod_eq_of_lt]
+    exact Nat.lt_of_le_of_lt (Nat.div_le_self ..) (by omega)

@[simp]
 theorem zero_udiv {x : BitVec w} : (0#w) / x = 0#w := by
@@ -2649,45 +2628,6 @@ theorem udiv_self {x : BitVec w} :
      ↓reduceIte, toNat_udiv]
    rw [Nat.div_self (by omega), Nat.mod_eq_of_lt (by omega)]

-theorem msb_udiv (x y : BitVec w) :
-    (x / y).msb = (x.msb && y == 1#w) := by
-  cases msb_x : x.msb
-  · suffices x.toNat / y.toNat < 2 ^ (w - 1) by simpa [msb_eq_decide]
-    calc
-      x.toNat / y.toNat ≤ x.toNat     := by apply Nat.div_le_self
-                      _ < 2 ^ (w - 1) := by simpa [msb_eq_decide] using msb_x
-  . rcases w with _|w
-    · contradiction
-    · have : (y == 1#_) = decide (y.toNat = 1) := by
-        simp [(· == ·), toNat_eq]
-      simp only [this, Bool.true_and]
-      match hy : y.toNat with
-      | 0 =>
-        obtain rfl : y = 0#_ := eq_of_toNat_eq hy
-        simp
-      | 1 =>
-        obtain rfl : y = 1#_ := eq_of_toNat_eq (by simp [hy])
-        simpa using msb_x
-      | y + 2 =>
-        suffices x.toNat / (y + 2) < 2 ^ w by
-          simp_all [msb_eq_decide, hy]
-        calc
-          x.toNat / (y + 2)
-            ≤ x.toNat / 2 := by apply Nat.div_add_le_right (by omega)
-          _ < 2 ^ w       := by omega
-
-theorem msb_udiv_eq_false_of {x : BitVec w} (h : x.msb = false) (y : BitVec w) :
-    (x / y).msb = false := by
-  simp [msb_udiv, h]
-
-/--
-If `x` is nonnegative (i.e., does not have its msb set),
-then `x / y` is nonnegative, thus `toInt` and `toNat` coincide.
-/
-theorem toInt_udiv_of_msb {x : BitVec w} (h : x.msb = false) (y : BitVec w) :
-    (x / y).toInt = x.toNat / y.toNat := by
-  simp [toInt_eq_msb_cond, msb_udiv_eq_false_of h]
-
 /-! ### umod -/

 theorem umod_def {x y : BitVec n} :
@@ -2700,10 +2640,6 @@ theorem umod_def {x y : BitVec n} :
 theorem toNat_umod {x y : BitVec n} :
    (x % y).toNat = x.toNat % y.toNat := rfl

-@[simp]
-theorem toFin_umod {x y : BitVec w} :
-    (x % y).toFin = x.toFin % y.toFin := rfl
-
@[simp]
 theorem umod_zero {x : BitVec n} : x % 0#n = x := by
  simp [umod_def]
@@ -2731,55 +2667,6 @@ theorem umod_eq_and {x y : BitVec 1} : x % y = x &&& (~~~y) := by
    rcases hy with rfl | rfl <;>
      rfl

-theorem umod_eq_of_lt {x y : BitVec w} (h : x < y) :
-    x % y = x := by
-  apply eq_of_toNat_eq
-  simp [Nat.mod_eq_of_lt h]
-
-@[simp]
-theorem msb_umod {x y : BitVec w} :
-    (x % y).msb = (x.msb && (x < y || y == 0#w)) := by
-  rw [msb_eq_decide, toNat_umod]
-  cases msb_x : x.msb
-  · suffices x.toNat % y.toNat < 2 ^ (w - 1) by simpa
-    calc
-      x.toNat % y.toNat ≤ x.toNat     := by apply Nat.mod_le
-                      _ < 2 ^ (w - 1) := by simpa [msb_eq_decide] using msb_x
-  . by_cases hy : y = 0
-    · simp_all [msb_eq_decide]
-    · suffices 2 ^ (w - 1) ≤ x.toNat % y.toNat ↔ x < y by simp_all
-      by_cases x_lt_y : x < y
-      . simp_all [Nat.mod_eq_of_lt x_lt_y, msb_eq_decide]
-      · suffices x.toNat % y.toNat < 2 ^ (w - 1) by
-          simpa [x_lt_y]
-        have y_le_x : y.toNat ≤ x.toNat := by
-          simpa using x_lt_y
-        replace hy : y.toNat ≠ 0 :=
-          toNat_ne_iff_ne.mpr hy
-        by_cases msb_y : y.toNat < 2 ^ (w - 1)
-        · have : x.toNat % y.toNat < y.toNat := Nat.mod_lt _ (by omega)
-          omega
-        · rcases w with _|w
-          · contradiction
-          simp only [Nat.add_one_sub_one]
-          replace msb_y : 2 ^ w ≤ y.toNat := by
-            simpa using msb_y
-          have : y.toNat ≤ y.toNat * (x.toNat / y.toNat) := by
-              apply Nat.le_mul_of_pos_right
-              apply Nat.div_pos y_le_x
-              omega
-          have : x.toNat % y.toNat ≤ x.toNat - y.toNat := by
-            rw [Nat.mod_eq_sub]; omega
-          omega
-
-theorem toInt_umod {x y : BitVec w} :
-    (x % y).toInt = (x.toNat % y.toNat : Int).bmod (2 ^ w) := by
-  simp [toInt_eq_toNat_bmod]
-
-theorem toInt_umod_of_msb {x y : BitVec w} (h : x.msb = false) :
-    (x % y).toInt = x.toInt % y.toNat := by
-  simp [toInt_eq_msb_cond, h]
-
 /-! ### smtUDiv -/

 theorem smtUDiv_eq (x y : BitVec w) : smtUDiv x y = if y = 0#w then allOnes w else x / y := by
@@ -2936,12 +2823,7 @@ theorem smod_zero {x : BitVec n} : x.smod 0#n = x := by

 /-! # Rotate Left -/

-/--`rotateLeft` is defined in terms of left and right shifts. -/
-theorem rotateLeft_def {x : BitVec w} {r : Nat} :
-    x.rotateLeft r = (x <<< (r % w)) ||| (x >>> (w - r % w)) := by
-  simp only [rotateLeft, rotateLeftAux]
-
-/-- `rotateLeft` is invariant under `mod` by the bitwidth. -/
+/-- rotateLeft is invariant under `mod` by the bitwidth. -/
@[simp]
 theorem rotateLeft_mod_eq_rotateLeft {x : BitVec w} {r : Nat} :
    x.rotateLeft (r % w) = x.rotateLeft r := by
@@ -3085,18 +2967,8 @@ theorem msb_rotateLeft {m w : Nat} {x : BitVec w} :
  · simp
    omega

-@[simp]
-theorem toNat_rotateLeft {x : BitVec w} {r : Nat} :
-    (x.rotateLeft r).toNat = (x.toNat <<< (r % w)) % (2^w) ||| x.toNat >>> (w - r % w) := by
-  simp only [rotateLeft_def, toNat_shiftLeft, toNat_ushiftRight, toNat_or]
-
 /-! ## Rotate Right -/

-/-- `rotateRight` is defined in terms of left and right shifts. -/
-theorem rotateRight_def {x : BitVec w} {r : Nat} :
-    x.rotateRight r = (x >>> (r % w)) ||| (x <<< (w - r % w)) := by
-  simp only [rotateRight, rotateRightAux]
-
 /--
 Accessing bits in `x.rotateRight r` the range `[0, w-r)` is equal to
 accessing bits `x` in the range `[r, w)`.
@@ -3232,11 +3104,6 @@ theorem msb_rotateRight {r w : Nat} {x : BitVec w} :
    simp [h₁]
  · simp [show w = 0 by omega]

-@[simp]
-theorem toNat_rotateRight {x : BitVec w} {r : Nat} :
-    (x.rotateRight r).toNat = (x.toNat >>> (r % w)) ||| x.toNat <<< (w - r % w) % (2^w) := by
-  simp only [rotateRight_def, toNat_shiftLeft, toNat_ushiftRight, toNat_or]
-
 /- ## twoPow -/

 theorem twoPow_eq (w : Nat) (i : Nat) : twoPow w i = 1#w <<< i := by
@@ -3539,7 +3406,7 @@ theorem getLsbD_intMax (w : Nat) : (intMax w).getLsbD i = decide (i + 1 < w) :=

 /-! ### Non-overflow theorems -/

-/-- If `x.toNat + y.toNat < 2^w`, then the addition `(x + y)` does not overflow. -/
+/-- If `x.toNat * y.toNat < 2^w`, then the multiplication `(x * y)` does not overflow. -/
 theorem toNat_add_of_lt {w} {x y : BitVec w} (h : x.toNat + y.toNat < 2^w) :
    (x + y).toNat = x.toNat + y.toNat := by
  rw [BitVec.toNat_add, Nat.mod_eq_of_lt h]
--- a/src/Init/Data/List/Lemmas.lean
+++ b/src/Init/Data/List/Lemmas.lean
@@ -1,8 +1,7 @@
 /-
 Copyright (c) 2014 Parikshit Khanna. All rights reserved.
 Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Parikshit Khanna, Jeremy Avigad, Leonardo de Moura, Floris van Doorn, Mario Carneiro,
-  Kim Morrison
+Authors: Parikshit Khanna, Jeremy Avigad, Leonardo de Moura, Floris van Doorn, Mario Carneiro
 -/
 prelude
 import Init.Data.Bool
@@ -1076,31 +1075,9 @@ theorem forall_mem_map {f : α → β} {l : List α} {P : β → Prop} :

@[deprecated forall_mem_map (since := "2024-07-25")] abbrev forall_mem_map_iff := @forall_mem_map

-@[simp] theorem map_eq_nil_iff {f : α → β} {l : List α} : map f l = [] ↔ l = [] := by
-  constructor <;> exact fun _ => match l with | [] => rfl
-
-@[deprecated map_eq_nil_iff (since := "2024-09-05")] abbrev map_eq_nil := @map_eq_nil_iff
-
-theorem eq_nil_of_map_eq_nil {f : α → β} {l : List α} (h : map f l = []) : l = [] :=
-  map_eq_nil_iff.mp h
-
@[simp] theorem map_inj_left {f g : α → β} : map f l = map g l ↔ ∀ a ∈ l, f a = g a := by
  induction l <;> simp_all

-theorem map_inj_right {f : α → β} (w : ∀ x y, f x = f y → x = y) : map f l = map f l' ↔ l = l' := by
-  induction l generalizing l' with
-  | nil => simp
-  | cons a l ih =>
-    simp only [map_cons]
-    cases l' with
-    | nil => simp
-    | cons a' l' =>
-      simp only [map_cons, cons.injEq, ih, and_congr_left_iff]
-      intro h
-      constructor
-      · apply w
-      · simp +contextual
-
 theorem map_congr_left (h : ∀ a ∈ l, f a = g a) : map f l = map g l :=
  map_inj_left.2 h

@@ -1109,6 +1086,14 @@ theorem map_inj : map f = map g ↔ f = g := by
  · intro h; ext a; replace h := congrFun h [a]; simpa using h
  · intro h; subst h; rfl

+@[simp] theorem map_eq_nil_iff {f : α → β} {l : List α} : map f l = [] ↔ l = [] := by
+  constructor <;> exact fun _ => match l with | [] => rfl
+
+@[deprecated map_eq_nil_iff (since := "2024-09-05")] abbrev map_eq_nil := @map_eq_nil_iff
+
+theorem eq_nil_of_map_eq_nil {f : α → β} {l : List α} (h : map f l = []) : l = [] :=
+  map_eq_nil_iff.mp h
+
 theorem map_eq_cons_iff {f : α → β} {l : List α} :
    map f l = b :: l₂ ↔ ∃ a l₁, l = a :: l₁ ∧ f a = b ∧ map f l₁ = l₂ := by
  cases l
@@ -1129,10 +1114,6 @@ theorem map_eq_cons_iff' {f : α → β} {l : List α} :

@[deprecated map_eq_cons' (since := "2024-09-05")] abbrev map_eq_cons' := @map_eq_cons_iff'

-@[simp] theorem map_eq_singleton_iff {f : α → β} {l : List α} {b : β} :
-    map f l = [b] ↔ ∃ a, l = [a] ∧ f a = b := by
-  simp [map_eq_cons_iff]
-
 theorem map_eq_map_iff : map f l = map g l ↔ ∀ a ∈ l, f a = g a := by
  induction l <;> simp

@@ -1299,7 +1280,7 @@ theorem map_filter_eq_foldr (f : α → β) (p : α → Bool) (as : List α) :
@[simp] theorem filter_append {p : α → Bool} :
    ∀ (l₁ l₂ : List α), filter p (l₁ ++ l₂) = filter p l₁ ++ filter p l₂
  | [], _ => rfl
-  | a :: l₁, l₂ => by simp only [cons_append, filter]; split <;> simp [filter_append l₁]
+  | a :: l₁, l₂ => by simp [filter]; split <;> simp [filter_append l₁]

 theorem filter_eq_cons_iff {l} {a} {as} :
    filter p l = a :: as ↔
@@ -1508,34 +1489,6 @@ theorem filterMap_eq_cons_iff {l} {b} {bs} :
@[simp] theorem cons_append_fun (a : α) (as : List α) :
    (fun bs => ((a :: as) ++ bs)) = fun bs => a :: (as ++ bs) := rfl

-@[simp] theorem mem_append {a : α} {s t : List α} : a ∈ s ++ t ↔ a ∈ s ∨ a ∈ t := by
-  induction s <;> simp_all [or_assoc]
-
-theorem not_mem_append {a : α} {s t : List α} (h₁ : a ∉ s) (h₂ : a ∉ t) : a ∉ s ++ t :=
-  mt mem_append.1 $ not_or.mpr ⟨h₁, h₂⟩
-
-@[deprecated mem_append (since := "2025-01-13")]
-theorem mem_append_eq (a : α) (s t : List α) : (a ∈ s ++ t) = (a ∈ s ∨ a ∈ t) :=
-  propext mem_append
-
-@[deprecated mem_append_left (since := "2024-11-20")] abbrev mem_append_of_mem_left := @mem_append_left
-@[deprecated mem_append_right (since := "2024-11-20")] abbrev mem_append_of_mem_right := @mem_append_right
-
-/--
-See also `eq_append_cons_of_mem`, which proves a stronger version
-in which the initial list must not contain the element.
-/
-theorem append_of_mem {a : α} {l : List α} : a ∈ l → ∃ s t : List α, l = s ++ a :: t
-  | .head l => ⟨[], l, rfl⟩
-  | .tail b h => let ⟨s, t, h'⟩ := append_of_mem h; ⟨b::s, t, by rw [h', cons_append]⟩
-
-theorem mem_iff_append {a : α} {l : List α} : a ∈ l ↔ ∃ s t : List α, l = s ++ a :: t :=
-  ⟨append_of_mem, fun ⟨s, t, e⟩ => e ▸ by simp⟩
-
-theorem forall_mem_append {p : α → Prop} {l₁ l₂ : List α} :
-    (∀ (x) (_ : x ∈ l₁ ++ l₂), p x) ↔ (∀ (x) (_ : x ∈ l₁), p x) ∧ (∀ (x) (_ : x ∈ l₂), p x) := by
-  simp only [mem_append, or_imp, forall_and]
-
 theorem getElem_append {l₁ l₂ : List α} (i : Nat) (h : i < (l₁ ++ l₂).length) :
    (l₁ ++ l₂)[i] = if h' : i < l₁.length then l₁[i] else l₂[i - l₁.length]'(by simp at h h'; exact Nat.sub_lt_left_of_lt_add h' h) := by
  split <;> rename_i h'
@@ -1603,6 +1556,14 @@ theorem get_of_append {l : List α} (eq : l = l₁ ++ a :: l₂) (h : l₁.lengt
    l.get ⟨i, get_of_append_proof eq h⟩ = a := Option.some.inj <| by
  rw [← get?_eq_get, eq, get?_append_right (h ▸ Nat.le_refl _), h, Nat.sub_self]; rfl

+/--
+See also `eq_append_cons_of_mem`, which proves a stronger version
+in which the initial list must not contain the element.
+-/
+theorem append_of_mem {a : α} {l : List α} : a ∈ l → ∃ s t : List α, l = s ++ a :: t
+  | .head l => ⟨[], l, rfl⟩
+  | .tail b h => let ⟨s, t, h'⟩ := append_of_mem h; ⟨b::s, t, by rw [h', cons_append]⟩
+
@[simp 1100] theorem singleton_append : [x] ++ l = x :: l := rfl

 theorem append_inj :
@@ -1619,8 +1580,8 @@ theorem append_inj_left (h : s₁ ++ t₁ = s₂ ++ t₂) (hl : length s₁ = le

 /-- Variant of `append_inj` instead requiring equality of the lengths of the second lists. -/
 theorem append_inj' (h : s₁ ++ t₁ = s₂ ++ t₂) (hl : length t₁ = length t₂) : s₁ = s₂ ∧ t₁ = t₂ :=
-  append_inj h <| @Nat.add_right_cancel _ t₁.length _ <| by
-    let hap := congrArg length h; simp only [length_append, ← hl] at hap; exact hap
+  append_inj h <| @Nat.add_right_cancel _ (length t₁) _ <| by
+  let hap := congrArg length h; simp only [length_append, ← hl] at hap; exact hap

 /-- Variant of `append_inj_right` instead requiring equality of the lengths of the second lists. -/
 theorem append_inj_right' (h : s₁ ++ t₁ = s₂ ++ t₂) (hl : length t₁ = length t₂) : t₁ = t₂ :=
@@ -1648,6 +1609,9 @@ theorem append_left_inj {s₁ s₂ : List α} (t) : s₁ ++ t = s₂ ++ t ↔ s
@[simp] theorem self_eq_append_right {x y : List α} : x = x ++ y ↔ y = [] := by
  rw [eq_comm, append_right_eq_self]

+@[simp] theorem append_eq_nil : p ++ q = [] ↔ p = [] ∧ q = [] := by
+  cases p <;> simp
+
 theorem getLast_concat {a : α} : ∀ (l : List α), getLast (l ++ [a]) (by simp) = a
  | [] => rfl
  | a::t => by
@@ -1673,54 +1637,6 @@ theorem get?_append {l₁ l₂ : List α} {n : Nat} (hn : n < l₁.length) :
    (l₁ ++ l₂).get? n = l₁.get? n := by
  simp [getElem?_append_left hn]

-@[simp] theorem append_eq_nil_iff : p ++ q = [] ↔ p = [] ∧ q = [] := by
-  cases p <;> simp
-
-@[deprecated append_eq_nil_iff (since := "2025-01-13")] abbrev append_eq_nil := @append_eq_nil_iff
-
-@[simp] theorem nil_eq_append_iff : [] = a ++ b ↔ a = [] ∧ b = [] := by
-  rw [eq_comm, append_eq_nil_iff]
-
-@[deprecated nil_eq_append_iff (since := "2024-07-24")] abbrev nil_eq_append := @nil_eq_append_iff
-
-theorem append_ne_nil_of_left_ne_nil {s : List α} (h : s ≠ []) (t : List α) : s ++ t ≠ [] := by simp_all
-theorem append_ne_nil_of_right_ne_nil (s : List α) : t ≠ [] → s ++ t ≠ [] := by simp_all
-
-@[deprecated append_ne_nil_of_left_ne_nil (since := "2024-07-24")]
-theorem append_ne_nil_of_ne_nil_left {s : List α} (h : s ≠ []) (t : List α) : s ++ t ≠ [] := by simp_all
-@[deprecated append_ne_nil_of_right_ne_nil (since := "2024-07-24")]
-theorem append_ne_nil_of_ne_nil_right (s : List α) : t ≠ [] → s ++ t ≠ [] := by simp_all
-
-theorem append_eq_cons_iff :
-    a ++ b = x :: c ↔ (a = [] ∧ b = x :: c) ∨ (∃ a', a = x :: a' ∧ c = a' ++ b) := by
-  cases a with simp | cons a as => ?_
-  exact ⟨fun h => ⟨as, by simp [h]⟩, fun ⟨a', ⟨aeq, aseq⟩, h⟩ => ⟨aeq, by rw [aseq, h]⟩⟩
-
-@[deprecated append_eq_cons_iff (since := "2024-07-24")] abbrev append_eq_cons := @append_eq_cons_iff
-
-theorem cons_eq_append_iff :
-    x :: c = a ++ b ↔ (a = [] ∧ b = x :: c) ∨ (∃ a', a = x :: a' ∧ c = a' ++ b) := by
-  rw [eq_comm, append_eq_cons_iff]
-
-@[deprecated cons_eq_append_iff (since := "2024-07-24")] abbrev cons_eq_append := @cons_eq_append_iff
-
-theorem append_eq_singleton_iff :
-    a ++ b = [x] ↔ (a = [] ∧ b = [x]) ∨ (a = [x] ∧ b = []) := by
-  cases a <;> cases b <;> simp
-
-theorem singleton_eq_append_iff :
-    [x] = a ++ b ↔ (a = [] ∧ b = [x]) ∨ (a = [x] ∧ b = []) := by
-  cases a <;> cases b <;> simp [eq_comm]
-
-theorem append_eq_append_iff {a b c d : List α} :
-    a ++ b = c ++ d ↔ (∃ a', c = a ++ a' ∧ b = a' ++ d) ∨ ∃ c', a = c ++ c' ∧ d = c' ++ b := by
-  induction a generalizing c with
-  | nil => simp_all
-  | cons a as ih => cases c <;> simp [eq_comm, and_assoc, ih, and_or_left]
-
-@[deprecated append_inj (since := "2024-07-24")] abbrev append_inj_of_length_left := @append_inj
-@[deprecated append_inj' (since := "2024-07-24")] abbrev append_inj_of_length_right := @append_inj'
-
@[simp] theorem head_append_of_ne_nil {l : List α} {w₁} (w₂) :
    head (l ++ l') w₁ = head l w₂ := by
  match l, w₂ with
@@ -1770,6 +1686,60 @@ theorem tail_append {l l' : List α} : (l ++ l').tail = if l.isEmpty then l'.tai

@[deprecated tail_append_of_ne_nil (since := "2024-07-24")] abbrev tail_append_left := @tail_append_of_ne_nil

+theorem nil_eq_append_iff : [] = a ++ b ↔ a = [] ∧ b = [] := by
+  rw [eq_comm, append_eq_nil]
+
+@[deprecated nil_eq_append_iff (since := "2024-07-24")] abbrev nil_eq_append := @nil_eq_append_iff
+
+theorem append_ne_nil_of_left_ne_nil {s : List α} (h : s ≠ []) (t : List α) : s ++ t ≠ [] := by simp_all
+theorem append_ne_nil_of_right_ne_nil (s : List α) : t ≠ [] → s ++ t ≠ [] := by simp_all
+
+@[deprecated append_ne_nil_of_left_ne_nil (since := "2024-07-24")]
+theorem append_ne_nil_of_ne_nil_left {s : List α} (h : s ≠ []) (t : List α) : s ++ t ≠ [] := by simp_all
+@[deprecated append_ne_nil_of_right_ne_nil (since := "2024-07-24")]
+theorem append_ne_nil_of_ne_nil_right (s : List α) : t ≠ [] → s ++ t ≠ [] := by simp_all
+
+theorem append_eq_cons_iff :
+    a ++ b = x :: c ↔ (a = [] ∧ b = x :: c) ∨ (∃ a', a = x :: a' ∧ c = a' ++ b) := by
+  cases a with simp | cons a as => ?_
+  exact ⟨fun h => ⟨as, by simp [h]⟩, fun ⟨a', ⟨aeq, aseq⟩, h⟩ => ⟨aeq, by rw [aseq, h]⟩⟩
+
+@[deprecated append_eq_cons_iff (since := "2024-07-24")] abbrev append_eq_cons := @append_eq_cons_iff
+
+theorem cons_eq_append_iff :
+    x :: c = a ++ b ↔ (a = [] ∧ b = x :: c) ∨ (∃ a', a = x :: a' ∧ c = a' ++ b) := by
+  rw [eq_comm, append_eq_cons_iff]
+
+@[deprecated cons_eq_append_iff (since := "2024-07-24")] abbrev cons_eq_append := @cons_eq_append_iff
+
+theorem append_eq_append_iff {a b c d : List α} :
+    a ++ b = c ++ d ↔ (∃ a', c = a ++ a' ∧ b = a' ++ d) ∨ ∃ c', a = c ++ c' ∧ d = c' ++ b := by
+  induction a generalizing c with
+  | nil => simp_all
+  | cons a as ih => cases c <;> simp [eq_comm, and_assoc, ih, and_or_left]
+
+@[deprecated append_inj (since := "2024-07-24")] abbrev append_inj_of_length_left := @append_inj
+@[deprecated append_inj' (since := "2024-07-24")] abbrev append_inj_of_length_right := @append_inj'
+
+@[simp] theorem mem_append {a : α} {s t : List α} : a ∈ s ++ t ↔ a ∈ s ∨ a ∈ t := by
+  induction s <;> simp_all [or_assoc]
+
+theorem not_mem_append {a : α} {s t : List α} (h₁ : a ∉ s) (h₂ : a ∉ t) : a ∉ s ++ t :=
+  mt mem_append.1 $ not_or.mpr ⟨h₁, h₂⟩
+
+theorem mem_append_eq (a : α) (s t : List α) : (a ∈ s ++ t) = (a ∈ s ∨ a ∈ t) :=
+  propext mem_append
+
+@[deprecated mem_append_left (since := "2024-11-20")] abbrev mem_append_of_mem_left := @mem_append_left
+@[deprecated mem_append_right (since := "2024-11-20")] abbrev mem_append_of_mem_right := @mem_append_right
+
+theorem mem_iff_append {a : α} {l : List α} : a ∈ l ↔ ∃ s t : List α, l = s ++ a :: t :=
+  ⟨append_of_mem, fun ⟨s, t, e⟩ => e ▸ by simp⟩
+
+theorem forall_mem_append {p : α → Prop} {l₁ l₂ : List α} :
+    (∀ (x) (_ : x ∈ l₁ ++ l₂), p x) ↔ (∀ (x) (_ : x ∈ l₁), p x) ∧ (∀ (x) (_ : x ∈ l₂), p x) := by
+  simp only [mem_append, or_imp, forall_and]
+
 theorem set_append {s t : List α} :
    (s ++ t).set i x = if i < s.length then s.set i x ++ t else s ++ t.set (i - s.length) x := by
  induction s generalizing i with
@@ -1898,7 +1868,7 @@ theorem eq_nil_or_concat : ∀ l : List α, l = [] ∨ ∃ L b, l = concat L b

 /-! ### flatten -/

-@[simp] theorem length_flatten (L : List (List α)) : L.flatten.length = (L.map length).sum := by
+@[simp] theorem length_flatten (L : List (List α)) : (flatten L).length = (L.map length).sum := by
  induction L with
  | nil => rfl
  | cons =>
@@ -1913,9 +1883,6 @@ theorem flatten_singleton (l : List α) : [l].flatten = l := by simp
@[simp] theorem flatten_eq_nil_iff {L : List (List α)} : L.flatten = [] ↔ ∀ l ∈ L, l = [] := by
  induction L <;> simp_all

-@[simp] theorem nil_eq_flatten_iff {L : List (List α)} : [] = L.flatten ↔ ∀ l ∈ L, l = [] := by
-  rw [eq_comm, flatten_eq_nil_iff]
-
 theorem flatten_ne_nil_iff {xs : List (List α)} : xs.flatten ≠ [] ↔ ∃ x, x ∈ xs ∧ x ≠ [] := by
  simp

@@ -1941,8 +1908,7 @@ theorem head?_flatten {L : List (List α)} : (flatten L).head? = L.findSome? fun
 -- `getLast?_flatten` is proved later, after the `reverse` section.
 -- `head_flatten` and `getLast_flatten` are proved in `Init.Data.List.Find`.

-@[simp] theorem map_flatten (f : α → β) (L : List (List α)) :
-    (flatten L).map f = (map (map f) L).flatten := by
+@[simp] theorem map_flatten (f : α → β) (L : List (List α)) : map f (flatten L) = flatten (map (map f) L) := by
  induction L <;> simp_all

@[simp] theorem filterMap_flatten (f : α → Option β) (L : List (List α)) :
@@ -1995,26 +1961,6 @@ theorem flatten_eq_cons_iff {xs : List (List α)} {y : α} {ys : List α} :
  · rintro ⟨as, bs, cs, rfl, h₁, rfl⟩
    simp [flatten_eq_nil_iff.mpr h₁]

-theorem cons_eq_flatten_iff {xs : List (List α)} {y : α} {ys : List α} :
-    y :: ys = xs.flatten ↔
-      ∃ as bs cs, xs = as ++ (y :: bs) :: cs ∧ (∀ l, l ∈ as → l = []) ∧ ys = bs ++ cs.flatten := by
-  rw [eq_comm, flatten_eq_cons_iff]
-
-theorem flatten_eq_singleton_iff {xs : List (List α)} {y : α} :
-    xs.flatten = [y] ↔ ∃ as bs, xs = as ++ [y] :: bs ∧ (∀ l, l ∈ as → l = []) ∧ (∀ l, l ∈ bs → l = []) := by
-  rw [flatten_eq_cons_iff]
-  constructor
-  · rintro ⟨as, bs, cs, rfl, h₁, h₂⟩
-    simp at h₂
-    obtain ⟨rfl, h₂⟩ := h₂
-    exact ⟨as, cs, by simp, h₁, h₂⟩
-  · rintro ⟨as, bs, rfl, h₁, h₂⟩
-    exact ⟨as, [], bs, rfl, h₁, by simpa⟩
-
-theorem singleton_eq_flatten_iff {xs : List (List α)} {y : α} :
-    [y] = xs.flatten ↔ ∃ as bs, xs = as ++ [y] :: bs ∧ (∀ l, l ∈ as → l = []) ∧ (∀ l, l ∈ bs → l = []) := by
-  rw [eq_comm, flatten_eq_singleton_iff]
-
 theorem flatten_eq_append_iff {xs : List (List α)} {ys zs : List α} :
    xs.flatten = ys ++ zs ↔
      (∃ as bs, xs = as ++ bs ∧ ys = as.flatten ∧ zs = bs.flatten) ∨
@@ -2023,8 +1969,8 @@ theorem flatten_eq_append_iff {xs : List (List α)} {ys zs : List α} :
  constructor
  · induction xs generalizing ys with
    | nil =>
-      simp only [flatten_nil, nil_eq, append_eq_nil_iff, and_false, cons_append, false_and,
-        exists_const, exists_false, or_false, and_imp, List.cons_ne_nil]
+      simp only [flatten_nil, nil_eq, append_eq_nil, and_false, cons_append, false_and, exists_const,
+        exists_false, or_false, and_imp, List.cons_ne_nil]
      rintro rfl rfl
      exact ⟨[], [], by simp⟩
    | cons x xs ih =>
@@ -2043,13 +1989,6 @@ theorem flatten_eq_append_iff {xs : List (List α)} {ys zs : List α} :
    · simp
    · simp

-theorem append_eq_flatten_iff {xs : List (List α)} {ys zs : List α} :
-    ys ++ zs = xs.flatten ↔
-      (∃ as bs, xs = as ++ bs ∧ ys = as.flatten ∧ zs = bs.flatten) ∨
-        ∃ as bs c cs ds, xs = as ++ (bs ++ c :: cs) :: ds ∧ ys = as.flatten ++ bs ∧
-          zs = c :: cs ++ ds.flatten := by
-  rw [eq_comm, flatten_eq_append_iff]
-
 /-- Two lists of sublists are equal iff their flattens coincide, as well as the lengths of the
 sublists. -/
 theorem eq_iff_flatten_eq : ∀ {L L' : List (List α)},
@@ -2072,8 +2011,6 @@ theorem flatMap_def (l : List α) (f : α → List β) : l.flatMap f = flatten (

@[simp] theorem flatMap_id (l : List (List α)) : List.flatMap l id = l.flatten := by simp [flatMap_def]

-@[simp] theorem flatMap_id' (l : List (List α)) : List.flatMap l (fun a => a) = l.flatten := by simp [flatMap_def]
-
@[simp]
 theorem length_flatMap (l : List α) (f : α → List β) :
    length (l.flatMap f) = sum (map (length ∘ f) l) := by
@@ -2395,9 +2332,6 @@ theorem replicateRecOn {α : Type _} {p : List α → Prop} (m : List α)
    exact hi _ _ _ _ h hn (replicateRecOn (b :: l') h0 hr hi)
 termination_by m.length

-@[simp] theorem sum_replicate_nat (n : Nat) (a : Nat) : (replicate n a).sum = n * a := by
-  induction n <;> simp_all [replicate_succ, Nat.add_mul, Nat.add_comm]
-
 /-! ### reverse -/

@[simp] theorem length_reverse (as : List α) : (as.reverse).length = as.length := by
--- a/src/Init/Data/List/ToArray.lean
+++ b/src/Init/Data/List/ToArray.lean
@@ -46,7 +46,7 @@ theorem toArray_cons (a : α) (l : List α) : (a :: l).toArray = #[a] ++ l.toArr
@[simp] theorem isEmpty_toArray (l : List α) : l.toArray.isEmpty = l.isEmpty := by
  cases l <;> simp [Array.isEmpty]

-@[simp] theorem toArray_singleton (a : α) : (List.singleton a).toArray = Array.singleton a := rfl
+@[simp] theorem toArray_singleton (a : α) : (List.singleton a).toArray = singleton a := rfl

@[simp] theorem back!_toArray [Inhabited α] (l : List α) : l.toArray.back! = l.getLast! := by
  simp only [back!, size_toArray, Array.get!_eq_getElem!, getElem!_toArray, getLast!_eq_getElem!]
@@ -143,9 +143,6 @@ theorem forM_toArray [Monad m] (l : List α) (f : α → m PUnit) :
  subst h
  rw [foldl_toList]

-@[simp] theorem sum_toArray [Add α] [Zero α] (l : List α) : l.toArray.sum = l.sum := by
-  simp [Array.sum, List.sum]
-
@[simp] theorem append_toArray (l₁ l₂ : List α) :
    l₁.toArray ++ l₂.toArray = (l₁ ++ l₂).toArray := by
  apply ext'
@@ -397,24 +394,4 @@ theorem takeWhile_go_toArray (p : α → Bool) (l : List α) (i : Nat) :
@[deprecated toArray_replicate (since := "2024-12-13")]
 abbrev _root_.Array.mkArray_eq_toArray_replicate := @toArray_replicate

-@[simp] theorem flatMap_empty {β} (f : α → Array β) : (#[] : Array α).flatMap f = #[] := rfl
-
-theorem flatMap_toArray_cons {β} (f : α → Array β) (a : α) (as : List α) :
-    (a :: as).toArray.flatMap f = f a ++ as.toArray.flatMap f := by
-  simp [Array.flatMap]
-  suffices ∀ cs, List.foldl (fun bs a => bs ++ f a) (f a ++ cs) as =
-      f a ++ List.foldl (fun bs a => bs ++ f a) cs as by
-    erw [empty_append] -- Why doesn't this work via `simp`?
-    simpa using this #[]
-  intro cs
-  induction as generalizing cs <;> simp_all
-
-@[simp] theorem flatMap_toArray {β} (f : α → Array β) (as : List α) :
-    as.toArray.flatMap f = (as.flatMap (fun a => (f a).toList)).toArray := by
-  induction as with
-  | nil => simp
-  | cons a as ih =>
-    apply ext'
-    simp [ih, flatMap_toArray_cons]
-
 end List
--- a/src/Init/Data/List/Zip.lean
+++ b/src/Init/Data/List/Zip.lean
@@ -203,11 +203,11 @@ theorem zipWith_eq_append_iff {f : α → β → γ} {l₁ : List α} {l₂ : Li
    cases l₂ with
    | nil =>
      constructor
-      · simp only [zipWith_nil_right, nil_eq, append_eq_nil_iff, exists_and_left, and_imp]
+      · simp only [zipWith_nil_right, nil_eq, append_eq_nil, exists_and_left, and_imp]
        rintro rfl  rfl
        exact ⟨[], x₁ :: l₁, [], by simp⟩
      · rintro ⟨w, x, y, z, h₁, _, h₃, rfl, rfl⟩
-        simp only [nil_eq, append_eq_nil_iff] at h₃
+        simp only [nil_eq, append_eq_nil] at h₃
        obtain ⟨rfl, rfl⟩ := h₃
        simp
    | cons x₂ l₂ =>
--- a/src/Init/Data/Nat/Div/Lemmas.lean
+++ b/src/Init/Data/Nat/Div/Lemmas.lean
@@ -49,17 +49,4 @@ theorem lt_div_mul_self (h : 0 < k) (w : k ≤ x) : x - k < x / k * k := by
  have : x % k < k := mod_lt x h
  omega

-theorem div_pos (hba : b ≤ a) (hb : 0 < b) : 0 < a / b := by
-  cases b
-  · contradiction
-  · simp [Nat.pos_iff_ne_zero, div_eq_zero_iff_lt, hba]
-
-theorem div_le_div_left (hcb : c ≤ b) (hc : 0 < c) : a / b ≤ a / c :=
-  (Nat.le_div_iff_mul_le hc).2 <|
-    Nat.le_trans (Nat.mul_le_mul_left _ hcb) (Nat.div_mul_le_self a b)
-
-theorem div_add_le_right {z : Nat} (h : 0 < z) (x y : Nat) :
-    x / (y + z) ≤ x / z :=
-  div_le_div_left (Nat.le_add_left z y) h
-
 end Nat
--- a/src/Init/Data/Option/Lemmas.lean
+++ b/src/Init/Data/Option/Lemmas.lean
@@ -208,15 +208,6 @@ theorem comp_map (h : β → γ) (g : α → β) (x : Option α) : x.map (h ∘

 theorem mem_map_of_mem (g : α → β) (h : a ∈ x) : g a ∈ Option.map g x := h.symm ▸ map_some' ..

-theorem map_inj_right {f : α → β} {o o' : Option α} (w : ∀ x y, f x = f y → x = y) :
-    o.map f = o'.map f ↔ o = o' := by
-  cases o with
-  | none => cases o' <;> simp
-  | some a =>
-    cases o' with
-    | none => simp
-    | some a' => simpa using ⟨fun h => w _ _ h, fun h => congrArg f h⟩
-
@[simp] theorem map_if {f : α → β} [Decidable c] :
     (if c then some a else none).map f = if c then some (f a) else none := by
  split <;> rfl
@@ -638,15 +629,6 @@ theorem pbind_eq_some_iff {o : Option α} {f : (a : α) → a ∈ o → Option
    · rintro ⟨h, rfl⟩
      rfl

-@[simp]
-theorem pmap_eq_map (p : α → Prop) (f : α → β) (o : Option α) (H) :
-    @pmap _ _ p (fun a _ => f a) o H = Option.map f o := by
-  cases o <;> simp
-
-theorem map_pmap {p : α → Prop} (g : β → γ) (f : ∀ a, p a → β) (o H) :
-    Option.map g (pmap f o H) = pmap (fun a h => g (f a h)) o H := by
-  cases o <;> simp
-
 /-! ### pelim -/

@[simp] theorem pelim_none : pelim none b f = b := rfl
--- a/src/Init/Data/UInt/Basic.lean
+++ b/src/Init/Data/UInt/Basic.lean
@@ -159,8 +159,6 @@ def UInt32.xor (a b : UInt32) : UInt32 := ⟨a.toBitVec ^^^ b.toBitVec⟩
 def UInt32.shiftLeft (a b : UInt32) : UInt32 := ⟨a.toBitVec <<< (mod b 32).toBitVec⟩
@[extern "lean_uint32_shift_right"]
 def UInt32.shiftRight (a b : UInt32) : UInt32 := ⟨a.toBitVec >>> (mod b 32).toBitVec⟩
-def UInt32.lt (a b : UInt32) : Prop := a.toBitVec < b.toBitVec
-def UInt32.le (a b : UInt32) : Prop := a.toBitVec ≤ b.toBitVec

 instance : Add UInt32       := ⟨UInt32.add⟩
 instance : Sub UInt32       := ⟨UInt32.sub⟩
@@ -171,8 +169,6 @@ set_option linter.deprecated false in
 instance : HMod UInt32 Nat UInt32 := ⟨UInt32.modn⟩

 instance : Div UInt32       := ⟨UInt32.div⟩
-instance : LT UInt32        := ⟨UInt32.lt⟩
-instance : LE UInt32        := ⟨UInt32.le⟩

@[extern "lean_uint32_complement"]
 def UInt32.complement (a : UInt32) : UInt32 := ⟨~~~a.toBitVec⟩
--- a/src/Init/Data/UInt/Bitwise.lean
+++ b/src/Init/Data/UInt/Bitwise.lean
@@ -13,12 +13,6 @@ macro "declare_bitwise_uint_theorems" typeName:ident bits:term:arg : command =>
 `(
 namespace $typeName

-@[simp] protected theorem toBitVec_add {a b : $typeName} : (a + b).toBitVec = a.toBitVec + b.toBitVec := rfl
-@[simp] protected theorem toBitVec_sub {a b : $typeName} : (a - b).toBitVec = a.toBitVec - b.toBitVec := rfl
-@[simp] protected theorem toBitVec_mul {a b : $typeName} : (a * b).toBitVec = a.toBitVec * b.toBitVec := rfl
-@[simp] protected theorem toBitVec_div {a b : $typeName} : (a / b).toBitVec = a.toBitVec / b.toBitVec := rfl
-@[simp] protected theorem toBitVec_mod {a b : $typeName} : (a % b).toBitVec = a.toBitVec % b.toBitVec := rfl
-@[simp] protected theorem toBitVec_not {a : $typeName} : (~~~a).toBitVec = ~~~a.toBitVec := rfl
@[simp] protected theorem toBitVec_and (a b : $typeName) : (a &&& b).toBitVec = a.toBitVec &&& b.toBitVec := rfl
@[simp] protected theorem toBitVec_or (a b : $typeName) : (a ||| b).toBitVec = a.toBitVec ||| b.toBitVec := rfl
@[simp] protected theorem toBitVec_xor (a b : $typeName) : (a ^^^ b).toBitVec = a.toBitVec ^^^ b.toBitVec := rfl
@@ -43,31 +37,3 @@ declare_bitwise_uint_theorems UInt16 16
 declare_bitwise_uint_theorems UInt32 32
 declare_bitwise_uint_theorems UInt64 64
 declare_bitwise_uint_theorems USize System.Platform.numBits
-
-@[simp]
-theorem Bool.toBitVec_toUInt8 {b : Bool} :
-    b.toUInt8.toBitVec = (BitVec.ofBool b).setWidth 8 := by
-  cases b <;> simp [toUInt8]
-
-@[simp]
-theorem Bool.toBitVec_toUInt16 {b : Bool} :
-    b.toUInt16.toBitVec = (BitVec.ofBool b).setWidth 16 := by
-  cases b <;> simp [toUInt16]
-
-@[simp]
-theorem Bool.toBitVec_toUInt32 {b : Bool} :
-    b.toUInt32.toBitVec = (BitVec.ofBool b).setWidth 32 := by
-  cases b <;> simp [toUInt32]
-
-@[simp]
-theorem Bool.toBitVec_toUInt64 {b : Bool} :
-    b.toUInt64.toBitVec = (BitVec.ofBool b).setWidth 64 := by
-  cases b <;> simp [toUInt64]
-
-@[simp]
-theorem Bool.toBitVec_toUSize {b : Bool} :
-    b.toUSize.toBitVec = (BitVec.ofBool b).setWidth System.Platform.numBits := by
-  cases b
-  · simp [toUSize]
-  · apply BitVec.eq_of_toNat_eq
-    simp [toUSize]
--- a/src/Init/Data/Vector/Basic.lean
+++ b/src/Init/Data/Vector/Basic.lean
@@ -103,7 +103,7 @@ of bounds.
@[inline] def head [NeZero n] (v : Vector α n) := v[0]'(Nat.pos_of_neZero n)

 /-- Push an element `x` to the end of a vector. -/
-@[inline] def push (v : Vector α n) (x : α) : Vector α (n + 1) :=
+@[inline] def push (x : α) (v : Vector α n)  : Vector α (n + 1) :=
  ⟨v.toArray.push x, by simp⟩

 /-- Remove the last element of a vector. -/
@@ -170,10 +170,6 @@ result is empty. If `stop` is greater than the size of the vector, the size is u
@[inline] def map (f : α → β) (v : Vector α n) : Vector β n :=
  ⟨v.toArray.map f, by simp⟩

-@[inline] def flatten (v : Vector (Vector α n) m) : Vector α (m * n) :=
-  ⟨(v.toArray.map Vector.toArray).flatten,
-    by rcases v; simp_all [Function.comp_def, Array.map_const']⟩
-
 /-- Maps corresponding elements of two vectors of equal size using the function `f`. -/
@[inline] def zipWith (a : Vector α n) (b : Vector β n) (f : α → β → φ) : Vector φ n :=
  ⟨Array.zipWith a.toArray b.toArray f, by simp⟩
--- a/src/Init/Data/Vector/Lemmas.lean
+++ b/src/Init/Data/Vector/Lemmas.lean
@@ -1,11 +1,10 @@
 /-
 Copyright (c) 2024 Shreyas Srinivas. All rights reserved.
 Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Shreyas Srinivas, Francois Dorais, Kim Morrison
+Authors: Shreyas Srinivas, Francois Dorais
 -/
 prelude
 import Init.Data.Vector.Basic
-import Init.Data.Array.Attach

 /-!
 ## Vectors
@@ -28,9 +27,6 @@ namespace Vector

 theorem toArray_mk (a : Array α) (h : a.size = n) : (Vector.mk a h).toArray = a := rfl

-@[simp] theorem mk_toArray (v : Vector α n) : mk v.toArray v.2 = v := by
-  rfl
-
@[simp] theorem getElem_mk {data : Array α} {size : data.size = n} {i : Nat} (h : i < n) :
    (Vector.mk data size)[i] = data[i] := rfl

@@ -157,14 +153,6 @@ theorem toArray_mk (a : Array α) (h : a.size = n) : (Vector.mk a h).toArray = a
@[simp] theorem all_mk (p : α → Bool) (a : Array α) (h : a.size = n) :
    (Vector.mk a h).all p = a.all p := rfl

-@[simp] theorem eq_mk : v = Vector.mk a h ↔ v.toArray = a := by
-  cases v
-  simp
-
-@[simp] theorem mk_eq : Vector.mk a h = v ↔ a = v.toArray := by
-  cases v
-  simp
-
 /-! ### toArray lemmas -/

@[simp] theorem getElem_toArray {α n} (xs : Vector α n) (i : Nat) (h : i < xs.toArray.size) :
@@ -697,24 +685,6 @@ theorem forall_getElem {l : Vector α n} {p : α → Prop} :
  rcases l with ⟨l, rfl⟩
  simp [Array.forall_getElem]

-
-/-! ### cast -/
-
-@[simp] theorem getElem_cast (a : Vector α n) (h : n = m) (i : Nat) (hi : i < m) :
-    (a.cast h)[i] = a[i] := by
-  cases a
-  simp
-
-@[simp] theorem getElem?_cast {l : Vector α n} {m : Nat} {w : n = m} {i : Nat} :
-    (l.cast w)[i]? = l[i]? := by
-  rcases l with ⟨l, rfl⟩
-  simp
-
-@[simp] theorem mem_cast {a : α} {l : Vector α n} {m : Nat} {w : n = m} :
-    a ∈ l.cast w ↔ a ∈ l := by
-  rcases l with ⟨l, rfl⟩
-  simp
-
 /-! ### Decidability of bounded quantifiers -/

 instance {xs : Vector α n} {p : α → Prop} [DecidablePred p] :
@@ -1065,6 +1035,8 @@ theorem mem_setIfInBounds (v : Vector α n) (i : Nat) (hi : i < n) (a : α) :
  cases l₂
  simp

+/-! Content below this point has not yet been aligned with `List` and `Array`. -/
+
 /-! ### map -/

@[simp] theorem getElem_map (f : α → β) (a : Vector α n) (i : Nat) (hi : i < n) :
@@ -1072,465 +1044,16 @@ theorem mem_setIfInBounds (v : Vector α n) (i : Nat) (hi : i < n) (a : α) :
  cases a
  simp

+@[simp] theorem getElem_ofFn {α n} (f : Fin n → α) (i : Nat) (h : i < n) :
+    (Vector.ofFn f)[i] = f ⟨i, by simpa using h⟩ := by
+  simp [ofFn]
+
 /-- The empty vector maps to the empty vector. -/
@[simp]
 theorem map_empty (f : α → β) : map f #v[] = #v[] := by
  rw [map, mk.injEq]
  exact Array.map_empty f

-@[simp] theorem map_push {f : α → β} {as : Vector α n} {x : α} :
-    (as.push x).map f = (as.map f).push (f x) := by
-  cases as
-  simp
-
-@[simp] theorem map_id_fun : map (n := n) (id : α → α) = id := by
-  funext l
-  induction l <;> simp_all
-
-/-- `map_id_fun'` differs from `map_id_fun` by representing the identity function as a lambda, rather than `id`. -/
-@[simp] theorem map_id_fun' : map (n := n) (fun (a : α) => a) = id := map_id_fun
-
-- This is not a `@[simp]` lemma because `map_id_fun` will apply.
-theorem map_id (l : Vector α n) : map (id : α → α) l = l := by
-  cases l <;> simp_all
-
-/-- `map_id'` differs from `map_id` by representing the identity function as a lambda, rather than `id`. -/
-- This is not a `@[simp]` lemma because `map_id_fun'` will apply.
-theorem map_id' (l : Vector α n) : map (fun (a : α) => a) l = l := map_id l
-
-/-- Variant of `map_id`, with a side condition that the function is pointwise the identity. -/
-theorem map_id'' {f : α → α} (h : ∀ x, f x = x) (l : Vector α n) : map f l = l := by
-  simp [show f = id from funext h]
-
-theorem map_singleton (f : α → β) (a : α) : map f #v[a] = #v[f a] := rfl
-
-@[simp] theorem mem_map {f : α → β} {l : Vector α n} : b ∈ l.map f ↔ ∃ a, a ∈ l ∧ f a = b := by
-  cases l
-  simp
-
-theorem exists_of_mem_map (h : b ∈ map f l) : ∃ a, a ∈ l ∧ f a = b := mem_map.1 h
-
-theorem mem_map_of_mem (f : α → β) (h : a ∈ l) : f a ∈ map f l := mem_map.2 ⟨_, h, rfl⟩
-
-theorem forall_mem_map {f : α → β} {l : Vector α n} {P : β → Prop} :
-    (∀ (i) (_ : i ∈ l.map f), P i) ↔ ∀ (j) (_ : j ∈ l), P (f j) := by
-  simp
-
-@[simp] theorem map_inj_left {f g : α → β} : map f l = map g l ↔ ∀ a ∈ l, f a = g a := by
-  cases l <;> simp_all
-
-theorem map_inj_right {f : α → β} (w : ∀ x y, f x = f y → x = y) : map f l = map f l' ↔ l = l' := by
-  cases l
-  cases l'
-  simp [Array.map_inj_right w]
-
-theorem map_congr_left (h : ∀ a ∈ l, f a = g a) : map f l = map g l :=
-  map_inj_left.2 h
-
-theorem map_inj [NeZero n] : map (n := n) f = map g ↔ f = g := by
-  constructor
-  · intro h
-    ext a
-    replace h := congrFun h (mkVector n a)
-    simp only [mkVector, map_mk, mk.injEq, Array.map_inj_left, Array.mem_mkArray,  and_imp,
-      forall_eq_apply_imp_iff] at h
-    exact h (NeZero.ne n)
-  · intro h; subst h; rfl
-
-theorem map_eq_push_iff {f : α → β} {l : Vector α (n + 1)} {l₂ : Vector β n} {b : β} :
-    map f l = l₂.push b ↔ ∃ l₁ a, l = l₁.push a ∧ map f l₁ = l₂ ∧ f a = b := by
-  rcases l with ⟨l, h⟩
-  rcases l₂ with ⟨l₂, rfl⟩
-  simp only [map_mk, push_mk, mk.injEq, Array.map_eq_push_iff]
-  constructor
-  · rintro ⟨l₁, a, rfl, rfl, rfl⟩
-    refine ⟨⟨l₁, by simp⟩, a, by simp⟩
-  · rintro ⟨l₁, a, h₁, h₂, rfl⟩
-    refine ⟨l₁.toArray, a, by simp_all⟩
-
-@[simp] theorem map_eq_singleton_iff {f : α → β} {l : Vector α 1} {b : β} :
-    map f l = #v[b] ↔ ∃ a, l = #v[a] ∧ f a = b := by
-  cases l
-  simp
-
-theorem map_eq_map_iff {f g : α → β} {l : Vector α n} :
-    map f l = map g l ↔ ∀ a ∈ l, f a = g a := by
-  cases l <;> simp_all
-
-theorem map_eq_iff {f : α → β} {l : Vector α n} {l' : Vector β n} :
-    map f l = l' ↔ ∀ i (h : i < n), l'[i] = f l[i] := by
-  rcases l with ⟨l, rfl⟩
-  rcases l' with ⟨l', h'⟩
-  simp only [map_mk, eq_mk, Array.map_eq_iff, getElem_mk]
-  constructor
-  · intro w i h
-    simpa [h, h'] using w i
-  · intro w i
-    if h : i < l.size then
-      simpa [h, h'] using w i h
-    else
-      rw [getElem?_neg, getElem?_neg, Option.map_none'] <;> omega
-
-@[simp] theorem map_set {f : α → β} {l : Vector α n} {i : Nat} {h : i < n} {a : α} :
-    (l.set i a).map f = (l.map f).set i (f a) (by simpa using h) := by
-  cases l
-  simp
-
-@[simp] theorem map_setIfInBounds {f : α → β} {l : Vector α n} {i : Nat} {a : α} :
-    (l.setIfInBounds i a).map f = (l.map f).setIfInBounds i (f a) := by
-  cases l
-  simp
-
-@[simp] theorem map_pop {f : α → β} {l : Vector α n} : l.pop.map f = (l.map f).pop := by
-  cases l
-  simp
-
-@[simp] theorem back?_map {f : α → β} {l : Vector α n} : (l.map f).back? = l.back?.map f := by
-  cases l
-  simp
-
-@[simp] theorem map_map {f : α → β} {g : β → γ} {as : Vector α n} :
-    (as.map f).map g = as.map (g ∘ f) := by
-  cases as
-  simp
-
-/--
-Use this as `induction ass using vector₂_induction` on a hypothesis of the form `ass : Vector (Vector α n) m`.
-The hypothesis `ass` will be replaced with a hypothesis `ass : Array (Array α)`
-along with additional hypotheses `h₁ : ass.size = m` and `h₂ : ∀ xs ∈ ass, xs.size = n`.
-Appearances of the original `ass` in the goal will be replaced with
-`Vector.mk (xss.attach.map (fun ⟨xs, m⟩ => Vector.mk xs ⋯)) ⋯`.
-/
-- We can't use `@[cases_eliminator]` here as
-- `Lean.Meta.getCustomEliminator?` only looks at the top-level constant.
-theorem vector₂_induction (P : Vector (Vector α n) m → Prop)
-    (of : ∀ (xss : Array (Array α)) (h₁ : xss.size = m) (h₂ : ∀ xs ∈ xss, xs.size = n),
-      P (mk (xss.attach.map (fun ⟨xs, m⟩ => mk xs (h₂ xs m))) (by simpa using h₁)))
-    (ass : Vector (Vector α n) m) : P ass := by
-  specialize of (ass.map toArray).toArray (by simp) (by simp)
-  simpa [Array.map_attach, Array.pmap_map] using of
-
-/--
-Use this as `induction ass using vector₃_induction` on a hypothesis of the form `ass : Vector (Vector (Vector α n) m) k`.
-The hypothesis `ass` will be replaced with a hypothesis `ass : Array (Array (Array α))`
-along with additional hypotheses `h₁ : ass.size = k`, `h₂ : ∀ xs ∈ ass, xs.size = m`,
-and `h₃ : ∀ xs ∈ ass, ∀ x ∈ xs, x.size = n`.
-Appearances of the original `ass` in the goal will be replaced with
-`Vector.mk (xss.attach.map (fun ⟨xs, m⟩ => Vector.mk (xs.attach.map (fun ⟨x, m'⟩ => Vector.mk x ⋯)) ⋯)) ⋯`.
-/
-theorem vector₃_induction (P : Vector (Vector (Vector α n) m) k → Prop)
-    (of : ∀ (xss : Array (Array (Array α))) (h₁ : xss.size = k) (h₂ : ∀ xs ∈ xss, xs.size = m)
-      (h₃ : ∀ xs ∈ xss, ∀ x ∈ xs, x.size = n),
-      P (mk (xss.attach.map (fun ⟨xs, m⟩ =>
-        mk (xs.attach.map (fun ⟨x, m'⟩ =>
-          mk x (h₃ xs m x m'))) (by simpa using h₂ xs m))) (by simpa using h₁)))
-    (ass : Vector (Vector (Vector α n) m) k) : P ass := by
-  specialize of (ass.map (fun as => (as.map toArray).toArray)).toArray (by simp) (by simp) (by simp)
-  simpa [Array.map_attach, Array.pmap_map] using of
-
-/-! ### singleton -/
-
-@[simp] theorem singleton_def (v : α) : Vector.singleton v = #v[v] := rfl
-
-/-! ### append -/
-
-@[simp] theorem append_push {as : Vector α n} {bs : Vector α m} {a : α} :
-    as ++ bs.push a = (as ++ bs).push a := by
-  cases as
-  cases bs
-  simp
-
-theorem singleton_eq_toVector_singleton (a : α) : #v[a] = #[a].toVector := rfl
-
-@[simp] theorem mem_append {a : α} {s : Vector α n} {t : Vector α m} :
-    a ∈ s ++ t ↔ a ∈ s ∨ a ∈ t := by
-  cases s
-  cases t
-  simp
-
-theorem mem_append_left {a : α} {s : Vector α n} {t : Vector α m} (h : a ∈ s) : a ∈ s ++ t :=
-  mem_append.2 (Or.inl h)
-
-theorem mem_append_right {a : α} {s : Vector α n} {t : Vector α m} (h : a ∈ t) : a ∈ s ++ t :=
-  mem_append.2 (Or.inr h)
-
-theorem not_mem_append {a : α} {s : Vector α n} {t : Vector α m} (h₁ : a ∉ s) (h₂ : a ∉ t) :
-    a ∉ s ++ t :=
-  mt mem_append.1 $ not_or.mpr ⟨h₁, h₂⟩
-
-/--
-See also `eq_push_append_of_mem`, which proves a stronger version
-in which the initial array must not contain the element.
-/
-theorem append_of_mem {a : α} {l : Vector α n} (h : a ∈ l) :
-    ∃ (m k : Nat) (w : m + 1 + k = n) (s : Vector α m) (t : Vector α k),
-      l = (s.push a ++ t).cast w := by
-  rcases l with ⟨l, rfl⟩
-  obtain ⟨s, t, rfl⟩ := Array.append_of_mem (by simpa using h)
-  refine ⟨_, _, by simp, s.toVector, t.toVector, by simp_all⟩
-
-theorem mem_iff_append {a : α} {l : Vector α n} :
-    a ∈ l ↔ ∃ (m k : Nat) (w : m + 1 + k = n) (s : Vector α m) (t : Vector α k),
-      l = (s.push a ++ t).cast w :=
-  ⟨append_of_mem, by rintro ⟨m, k, rfl, s, t, rfl⟩; simp⟩
-
-theorem forall_mem_append {p : α → Prop} {l₁ : Vector α n} {l₂ : Vector α m} :
-    (∀ (x) (_ : x ∈ l₁ ++ l₂), p x) ↔ (∀ (x) (_ : x ∈ l₁), p x) ∧ (∀ (x) (_ : x ∈ l₂), p x) := by
-  simp only [mem_append, or_imp, forall_and]
-
-theorem empty_append (as : Vector α n) : (#v[] : Vector α 0) ++ as = as.cast (by omega) := by
-  rcases as with ⟨as, rfl⟩
-  simp
-
-theorem append_empty (as : Vector α n) : as ++ (#v[] : Vector α 0) = as := by
-  rw [← toArray_inj, toArray_append, Array.append_empty]
-
-theorem getElem_append (a : Vector α n) (b : Vector α m) (i : Nat) (hi : i < n + m) :
-    (a ++ b)[i] = if h : i < n then a[i] else b[i - n] := by
-  rcases a with ⟨a, rfl⟩
-  rcases b with ⟨b, rfl⟩
-  simp [Array.getElem_append, hi]
-
-theorem getElem_append_left {a : Vector α n} {b : Vector α m} {i : Nat} (hi : i < n) :
-    (a ++ b)[i] = a[i] := by simp [getElem_append, hi]
-
-theorem getElem_append_right {a : Vector α n} {b : Vector α m} {i : Nat} (h : i < n + m) (hi : n ≤ i) :
-    (a ++ b)[i] = b[i - n] := by
-  rw [getElem_append, dif_neg (by omega)]
-
-theorem getElem?_append_left {as : Vector α n} {bs : Vector α m} {i : Nat} (hn : i < n) :
-    (as ++ bs)[i]? = as[i]? := by
-  have hn' : i < n + m := by omega
-  simp_all [getElem?_eq_getElem, getElem_append]
-
-theorem getElem?_append_right {as : Vector α n} {bs : Vector α m} {i : Nat} (h : n ≤ i) :
-    (as ++ bs)[i]? = bs[i - n]? := by
-  rcases as with ⟨as, rfl⟩
-  rcases bs with ⟨bs, rfl⟩
-  simp [Array.getElem?_append_right, h]
-
-theorem getElem?_append {as : Vector α n} {bs : Vector α m} {i : Nat} :
-    (as ++ bs)[i]? = if i < n then as[i]? else bs[i - n]? := by
-  split <;> rename_i h
-  · exact getElem?_append_left h
-  · exact getElem?_append_right (by simpa using h)
-
-/-- Variant of `getElem_append_left` useful for rewriting from the small array to the big array. -/
-theorem getElem_append_left' (l₁ : Vector α m) {l₂ : Vector α n} {i : Nat} (hi : i < m) :
-    l₁[i] = (l₁ ++ l₂)[i] := by
-  rw [getElem_append_left] <;> simp
-
-/-- Variant of `getElem_append_right` useful for rewriting from the small array to the big array. -/
-theorem getElem_append_right' (l₁ : Vector α m) {l₂ : Vector α n} {i : Nat} (hi : i < n) :
-    l₂[i] = (l₁ ++ l₂)[i + m] := by
-  rw [getElem_append_right] <;> simp [*, Nat.le_add_left]
-
-theorem getElem_of_append {l : Vector α n} {l₁ : Vector α m} {l₂ : Vector α k}
-    (w : m + 1 + k = n) (eq : l = (l₁.push a ++ l₂).cast w) :
-    l[m] = a := Option.some.inj <| by
-  rw [← getElem?_eq_getElem, eq, getElem?_cast, getElem?_append_left (by simp)]
-  simp
-
-@[simp 1100] theorem append_singleton {a : α} {as : Vector α n} : as ++ #v[a] = as.push a := by
-  cases as
-  simp
-
-theorem append_inj {s₁ s₂ : Vector α n} {t₁ t₂ : Vector α m} (h : s₁ ++ t₁ = s₂ ++ t₂) :
-    s₁ = s₂ ∧ t₁ = t₂ := by
-  rcases s₁ with ⟨s₁, rfl⟩
-  rcases s₂ with ⟨s₂, hs⟩
-  rcases t₁ with ⟨t₁, rfl⟩
-  rcases t₂ with ⟨t₂, ht⟩
-  simpa using Array.append_inj (by simpa using h) (by omega)
-
-theorem append_inj_right {s₁ s₂ : Vector α n} {t₁ t₂ : Vector α m}
-    (h : s₁ ++ t₁ = s₂ ++ t₂) : t₁ = t₂ :=
-  (append_inj h).right
-
-theorem append_inj_left {s₁ s₂ : Vector α n} {t₁ t₂ : Vector α m}
-    (h : s₁ ++ t₁ = s₂ ++ t₂) : s₁ = s₂ :=
-  (append_inj h).left
-
-theorem append_right_inj {t₁ t₂ : Vector α m} (s : Vector α n) : s ++ t₁ = s ++ t₂ ↔ t₁ = t₂ :=
-  ⟨fun h => append_inj_right h, congrArg _⟩
-
-theorem append_left_inj {s₁ s₂ : Vector α n} (t : Vector α m) : s₁ ++ t = s₂ ++ t ↔ s₁ = s₂ :=
-  ⟨fun h => append_inj_left h, congrArg (· ++ _)⟩
-
-theorem append_eq_append_iff {a : Vector α n} {b : Vector α m} {c : Vector α k} {d : Vector α l}
-    (w : k + l = n + m) :
-    a ++ b = (c ++ d).cast w ↔
-      if h : n ≤ k then
-        ∃ a' : Vector α (k - n), c = (a ++ a').cast (by omega) ∧ b = (a' ++ d).cast (by omega)
-      else
-        ∃ c' : Vector α (n - k), a = (c ++ c').cast (by omega) ∧ d = (c' ++ b).cast (by omega) := by
-  rcases a with ⟨a, rfl⟩
-  rcases b with ⟨b, rfl⟩
-  rcases c with ⟨c, rfl⟩
-  rcases d with ⟨d, rfl⟩
-  simp only [mk_append_mk, Array.append_eq_append_iff, mk_eq, toArray_cast]
-  constructor
-  · rintro (⟨a', rfl, rfl⟩ | ⟨c', rfl, rfl⟩)
-    · rw [dif_pos (by simp)]
-      exact ⟨a'.toVector.cast (by simp; omega), by simp⟩
-    · split <;> rename_i h
-      · have hc : c'.size = 0 := by simp at h; omega
-        simp at hc
-        exact ⟨#v[].cast (by simp; omega), by simp_all⟩
-      · exact ⟨c'.toVector.cast (by simp; omega), by simp⟩
-  · split <;> rename_i h
-    · rintro ⟨a', hc, rfl⟩
-      left
-      refine ⟨a'.toArray, hc, rfl⟩
-    · rintro ⟨c', ha, rfl⟩
-      right
-      refine ⟨c'.toArray, ha, rfl⟩
-
-theorem set_append {s : Vector α n} {t : Vector α m} {i : Nat} {x : α} (h : i < n + m) :
-    (s ++ t).set i x =
-      if h' : i < n then
-        s.set i x ++ t
-      else
-        s ++ t.set (i - n) x := by
-  rcases s with ⟨s, rfl⟩
-  rcases t with ⟨t, rfl⟩
-  simp only [mk_append_mk, set_mk, Array.set_append]
-  split <;> simp
-
-@[simp] theorem set_append_left {s : Vector α n} {t : Vector α m} {i : Nat} {x : α} (h : i < n) :
-    (s ++ t).set i x = s.set i x ++ t := by
-  simp [set_append, h]
-
-@[simp] theorem set_append_right {s : Vector α n} {t : Vector α m} {i : Nat} {x : α}
-    (h' : i < n + m) (h : n ≤ i) :
-    (s ++ t).set i x = s ++ t.set (i - n) x := by
-  rw [set_append, dif_neg (by omega)]
-
-theorem setIfInBounds_append {s : Vector α n} {t : Vector α m} {i : Nat} {x : α} :
-    (s ++ t).setIfInBounds i x =
-      if i < n then
-        s.setIfInBounds i x ++ t
-      else
-        s ++ t.setIfInBounds (i - n) x := by
-  rcases s with ⟨s, rfl⟩
-  rcases t with ⟨t, rfl⟩
-  simp only [mk_append_mk, setIfInBounds_mk, Array.setIfInBounds_append]
-  split <;> simp
-
-@[simp] theorem setIfInBounds_append_left {s : Vector α n} {t : Vector α m} {i : Nat} {x : α} (h : i < n) :
-    (s ++ t).setIfInBounds i x = s.setIfInBounds i x ++ t := by
-  simp [setIfInBounds_append, h]
-
-@[simp] theorem setIfInBounds_append_right {s : Vector α n} {t : Vector α m} {i : Nat} {x : α}
-    (h : n ≤ i) :
-    (s ++ t).setIfInBounds i x = s ++ t.setIfInBounds (i - n) x := by
-  rw [setIfInBounds_append, if_neg (by omega)]
-
-@[simp] theorem map_append (f : α → β) (l₁ : Vector α n) (l₂ : Vector α m) :
-    map f (l₁ ++ l₂) = map f l₁ ++ map f l₂ := by
-  rcases l₁ with ⟨l₁, rfl⟩
-  rcases l₂ with ⟨l₂, rfl⟩
-  simp
-
-theorem map_eq_append_iff {f : α → β} :
-    map f l = L₁ ++ L₂ ↔ ∃ l₁ l₂, l = l₁ ++ l₂ ∧ map f l₁ = L₁ ∧ map f l₂ = L₂ := by
-  rcases l with ⟨l, h⟩
-  rcases L₁ with ⟨L₁, rfl⟩
-  rcases L₂ with ⟨L₂, rfl⟩
-  simp only [map_mk, mk_append_mk, eq_mk, Array.map_eq_append_iff, mk_eq, toArray_append,
-    toArray_map]
-  constructor
-  · rintro ⟨l₁, l₂, rfl, rfl, rfl⟩
-    exact ⟨l₁.toVector.cast (by simp), l₂.toVector.cast (by simp), by simp⟩
-  · rintro ⟨⟨l₁⟩, ⟨l₂⟩, rfl, h₁, h₂⟩
-    exact ⟨l₁, l₂, by simp_all⟩
-
-theorem append_eq_map_iff {f : α → β} :
-    L₁ ++ L₂ = map f l ↔ ∃ l₁ l₂, l = l₁ ++ l₂ ∧ map f l₁ = L₁ ∧ map f l₂ = L₂ := by
-  rw [eq_comm, map_eq_append_iff]
-
-/-! ### flatten -/
-
-@[simp] theorem flatten_mk (L : Array (Vector α n)) (h : L.size = m) :
-    (mk L h).flatten =
-      mk (L.map toArray).flatten (by simp [Function.comp_def, Array.map_const', h]) := by
-  simp [flatten]
-
-@[simp] theorem flatten_singleton (l : Vector α n) : #v[l].flatten = l.cast (by simp) := by
-  simp [flatten]
-
-theorem mem_flatten {L : Vector (Vector α n) m} : a ∈ L.flatten ↔ ∃ l, l ∈ L ∧ a ∈ l := by
-  rcases L with ⟨L, rfl⟩
-  simp [Array.mem_flatten]
-  constructor
-  · rintro ⟨_, ⟨l, h₁, rfl⟩, h₂⟩
-    exact ⟨l, h₁, by simpa using h₂⟩
-  · rintro ⟨l, h₁, h₂⟩
-    exact ⟨l.toArray, ⟨l, h₁, rfl⟩, by simpa using h₂⟩
-
-theorem exists_of_mem_flatten : a ∈ flatten L → ∃ l, l ∈ L ∧ a ∈ l := mem_flatten.1
-
-theorem mem_flatten_of_mem (lL : l ∈ L) (al : a ∈ l) : a ∈ flatten L := mem_flatten.2 ⟨l, lL, al⟩
-
-theorem forall_mem_flatten {p : α → Prop} {L : Vector (Vector α n) m} :
-    (∀ (x) (_ : x ∈ flatten L), p x) ↔ ∀ (l) (_ : l ∈ L) (x) (_ : x ∈ l), p x := by
-  simp only [mem_flatten, forall_exists_index, and_imp]
-  constructor <;> (intros; solve_by_elim)
-
-@[simp] theorem map_flatten (f : α → β) (L : Vector (Vector α n) m) :
-    (flatten L).map f = (map (map f) L).flatten := by
-  induction L using vector₂_induction with
-  | of xss h₁ h₂ => simp
-
-@[simp] theorem flatten_append (L₁ : Vector (Vector α n) m₁) (L₂ : Vector (Vector α n) m₂) :
-    flatten (L₁ ++ L₂) = (flatten L₁ ++ flatten L₂).cast (by simp [Nat.add_mul]) := by
-  induction L₁ using vector₂_induction
-  induction L₂ using vector₂_induction
-  simp
-
-theorem flatten_push (L : Vector (Vector α n) m) (l : Vector α n) :
-    flatten (L.push l) = (flatten L ++ l).cast (by simp [Nat.add_mul]) := by
-  induction L using vector₂_induction
-  rcases l with ⟨l⟩
-  simp [Array.flatten_push]
-
-theorem flatten_flatten {L : Vector (Vector (Vector α n) m) k} :
-    flatten (flatten L) = (flatten (map flatten L)).cast (by simp [Nat.mul_assoc]) := by
-  induction L using vector₃_induction with
-  | of xss h₁ h₂ h₃ =>
-    -- simp [Array.flatten_flatten] -- FIXME: `simp` produces a bad proof here!
-    simp [Array.map_attach, Array.flatten_flatten, Array.map_pmap]
-
-/-- Two vectors of constant length vectors are equal iff their flattens coincide. -/
-theorem eq_iff_flatten_eq {L L' : Vector (Vector α n) m} :
-    L = L' ↔ L.flatten = L'.flatten := by
-  induction L using vector₂_induction with | of L h₁ h₂ =>
-  induction L' using vector₂_induction with | of L' h₁' h₂' =>
-  simp only [eq_mk, flatten_mk, Array.map_map, Function.comp_apply, Array.map_subtype,
-    Array.unattach_attach, Array.map_id_fun', id_eq]
-  constructor
-  · intro h
-    suffices L = L' by simp_all
-    apply Array.ext_getElem?
-    intro i
-    replace h := congrArg (fun x => x[i]?.map (fun x => x.toArray)) h
-    simpa [Option.map_pmap] using h
-  · intro h
-    have w : L.map Array.size = L'.map Array.size := by
-      ext i h h'
-      · simp_all
-      · simp only [Array.getElem_map]
-        rw [h₂ _ (by simp), h₂' _ (by simp)]
-    have := Array.eq_iff_flatten_eq.mpr ⟨h, w⟩
-    subst this
-    rfl
-
-/-! Content below this point has not yet been aligned with `List` and `Array`. -/
-
-@[simp] theorem getElem_ofFn {α n} (f : Fin n → α) (i : Nat) (h : i < n) :
-    (Vector.ofFn f)[i] = f ⟨i, by simpa using h⟩ := by
-  simp [ofFn]
-
@[simp] theorem getElem_push_last {v : Vector α n} {x : α} : (v.push x)[n] = x := by
  rcases v with ⟨data, rfl⟩
  simp
@@ -1555,6 +1078,28 @@ defeq issues in the implicit size argument.
    subst h
    simp [pop, back, back!, ← Array.eq_push_pop_back!_of_size_ne_zero]

+/-! ### append -/
+
+theorem getElem_append (a : Vector α n) (b : Vector α m) (i : Nat) (hi : i < n + m) :
+    (a ++ b)[i] = if h : i < n then a[i] else b[i - n] := by
+  rcases a with ⟨a, rfl⟩
+  rcases b with ⟨b, rfl⟩
+  simp [Array.getElem_append, hi]
+
+theorem getElem_append_left {a : Vector α n} {b : Vector α m} {i : Nat} (hi : i < n) :
+    (a ++ b)[i] = a[i] := by simp [getElem_append, hi]
+
+theorem getElem_append_right {a : Vector α n} {b : Vector α m} {i : Nat} (h : i < n + m) (hi : n ≤ i) :
+    (a ++ b)[i] = b[i - n] := by
+  rw [getElem_append, dif_neg (by omega)]
+
+/-! ### cast -/
+
+@[simp] theorem getElem_cast (a : Vector α n) (h : n = m) (i : Nat) (hi : i < m) :
+    (a.cast h)[i] = a[i] := by
+  cases a
+  simp
+
 /-! ### extract -/

@[simp] theorem getElem_extract (a : Vector α n) (start stop) (i : Nat) (hi : i < min stop n - start) :
--- a/src/Init/Grind.lean
+++ b/src/Init/Grind.lean
@@ -10,5 +10,3 @@ import Init.Grind.Lemmas
 import Init.Grind.Cases
 import Init.Grind.Propagator
 import Init.Grind.Util
-import Init.Grind.Offset
-import Init.Grind.PP
--- a/src/Init/Grind/Lemmas.lean
+++ b/src/Init/Grind/Lemmas.lean
@@ -12,9 +12,6 @@ import Init.Grind.Util

 namespace Lean.Grind

-theorem rfl_true : true = true :=
-  rfl
-
 theorem intro_with_eq (p p' q : Prop) (he : p = p') (h : p' → q) : p → q :=
  fun hp => h (he.mp hp)

@@ -69,12 +66,6 @@ theorem eq_eq_of_eq_true_right {a b : Prop} (h : b = True) : (a = b) = a := by s
 theorem eq_congr  {α : Sort u} {a₁ b₁ a₂ b₂ : α} (h₁ : a₁ = a₂) (h₂ : b₁ = b₂) : (a₁ = b₁) = (a₂ = b₂) := by simp [*]
 theorem eq_congr' {α : Sort u} {a₁ b₁ a₂ b₂ : α} (h₁ : a₁ = b₂) (h₂ : b₁ = a₂) : (a₁ = b₁) = (a₂ = b₂) := by rw [h₁, h₂, Eq.comm (a := a₂)]

-/- The following two helper theorems are used to case-split `a = b` representing `iff`. -/
-theorem of_eq_eq_true {a b : Prop} (h : (a = b) = True) : (¬a ∨ b) ∧ (¬b ∨ a) := by
-  by_cases a <;> by_cases b <;> simp_all
-theorem of_eq_eq_false {a b : Prop} (h : (a = b) = False) : (¬a ∨ ¬b) ∧ (b ∨ a) := by
-  by_cases a <;> by_cases b <;> simp_all
-
 /-! Forall -/

 theorem forall_propagator (p : Prop) (q : p → Prop) (q' : Prop) (h₁ : p = True) (h₂ : q (of_eq_true h₁) = q') : (∀ hp : p, q hp) = q' := by
--- a/src/Init/Grind/Norm.lean
+++ b/src/Init/Grind/Norm.lean
@@ -43,14 +43,8 @@ attribute [grind_norm] not_false_eq_true

 -- Remark: we disabled the following normalization rule because we want this information when implementing splitting heuristics
 -- Implication as a clause
-theorem imp_eq (p q : Prop) : (p → q) = (¬ p ∨ q) := by
-  by_cases p <;> by_cases q <;> simp [*]
-
-@[grind_norm] theorem true_imp_eq (p : Prop) : (True → p) = p := by simp
-@[grind_norm] theorem false_imp_eq (p : Prop) : (False → p) = True := by simp
-@[grind_norm] theorem imp_true_eq (p : Prop) : (p → True) = True := by simp
-@[grind_norm] theorem imp_false_eq (p : Prop) : (p → False) = ¬p := by simp
-@[grind_norm] theorem imp_self_eq (p : Prop) : (p → p) = True := by simp
+-- @[grind_norm↓] theorem imp_eq (p q : Prop) : (p → q) = (¬ p ∨ q) := by
+--  by_cases p <;> by_cases q <;> simp [*]

 -- And
@[grind_norm↓] theorem not_and (p q : Prop) : (¬(p ∧ q)) = (¬p ∨ ¬q) := by
--- a/src/Init/Grind/Offset.lean
+++ b/src/Init/Grind/Offset.lean
@@ -1,92 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Init.Core
-import Init.Omega
-
-namespace Lean.Grind
-abbrev isLt (x y : Nat) : Bool := x < y
-abbrev isLE (x y : Nat) : Bool := x ≤ y
-
-/-! Theorems for transitivity. -/
-theorem Nat.le_ro (u w v k : Nat) : u ≤ w → w ≤ v + k → u ≤ v + k := by
-  omega
-theorem Nat.le_lo (u w v k : Nat) : u ≤ w → w + k ≤ v → u + k ≤ v := by
-  omega
-theorem Nat.lo_le (u w v k : Nat) : u + k ≤ w → w ≤ v → u + k ≤ v := by
-  omega
-theorem Nat.lo_lo (u w v k₁ k₂ : Nat) : u + k₁ ≤ w → w + k₂ ≤ v → u + (k₁ + k₂) ≤ v := by
-  omega
-theorem Nat.lo_ro_1 (u w v k₁ k₂ : Nat) : isLt k₂ k₁ = true → u + k₁ ≤ w → w ≤ v + k₂ → u + (k₁ - k₂) ≤ v := by
-  simp [isLt]; omega
-theorem Nat.lo_ro_2 (u w v k₁ k₂ : Nat) : u + k₁ ≤ w → w ≤ v + k₂ → u ≤ v + (k₂ - k₁) := by
-  omega
-theorem Nat.ro_le (u w v k : Nat) : u ≤ w + k → w ≤ v → u ≤ v + k := by
-  omega
-theorem Nat.ro_lo_1 (u w v k₁ k₂ : Nat) : u ≤ w + k₁ → w + k₂ ≤ v → u ≤ v + (k₁ - k₂) := by
-  omega
-theorem Nat.ro_lo_2 (u w v k₁ k₂ : Nat) : isLt k₁ k₂ = true → u ≤ w + k₁ → w + k₂ ≤ v → u + (k₂ - k₁) ≤ v := by
-  simp [isLt]; omega
-theorem Nat.ro_ro (u w v k₁ k₂ : Nat) : u ≤ w + k₁ → w ≤ v + k₂ → u ≤ v + (k₁ + k₂) := by
-  omega
-
-/-! Theorems for negating constraints. -/
-theorem Nat.of_le_eq_false (u v : Nat) : ((u ≤ v) = False) → v + 1 ≤ u := by
-  simp; omega
-theorem Nat.of_lo_eq_false_1 (u v : Nat) : ((u + 1 ≤ v) = False) → v ≤ u := by
-  simp; omega
-theorem Nat.of_lo_eq_false (u v k : Nat) : ((u + k ≤ v) = False) → v ≤ u + (k-1) := by
-  simp; omega
-theorem Nat.of_ro_eq_false (u v k : Nat) : ((u ≤ v + k) = False) → v + (k+1) ≤ u := by
-  simp; omega
-
-/-! Theorems for closing a goal. -/
-theorem Nat.unsat_le_lo (u v k : Nat) : isLt 0 k = true → u ≤ v → v + k ≤ u → False := by
-  simp [isLt]; omega
-theorem Nat.unsat_lo_lo (u v k₁ k₂ : Nat) : isLt 0 (k₁+k₂) = true → u + k₁ ≤ v → v + k₂ ≤ u → False := by
-  simp [isLt]; omega
-theorem Nat.unsat_lo_ro (u v k₁ k₂ : Nat) : isLt k₂ k₁ = true → u + k₁ ≤ v → v ≤ u + k₂ → False := by
-  simp [isLt]; omega
-
-/-! Theorems for propagating constraints to `True` -/
-theorem Nat.lo_eq_true_of_lo (u v k₁ k₂ : Nat) : isLE k₂ k₁ = true → u + k₁ ≤ v → (u + k₂ ≤ v) = True :=
-  by simp [isLt]; omega
-theorem Nat.le_eq_true_of_lo (u v k : Nat) : u + k ≤ v → (u ≤ v) = True :=
-  by simp; omega
-theorem Nat.le_eq_true_of_le (u v : Nat) : u ≤ v → (u ≤ v) = True :=
-  by simp
-theorem Nat.ro_eq_true_of_lo (u v k₁ k₂ : Nat) : u + k₁ ≤ v → (u ≤ v + k₂) = True :=
-  by simp; omega
-theorem Nat.ro_eq_true_of_le (u v k : Nat) : u ≤ v → (u ≤ v + k) = True :=
-  by simp; omega
-theorem Nat.ro_eq_true_of_ro (u v k₁ k₂ : Nat) : isLE k₁ k₂ = true → u ≤ v + k₁ → (u ≤ v + k₂) = True :=
-  by simp [isLE]; omega
-
-/-!
-Theorems for propagating constraints to `False`.
-They are variants of the theorems for closing a goal.
-/
-theorem Nat.lo_eq_false_of_le (u v k : Nat) : isLt 0 k = true → u ≤ v → (v + k ≤ u) = False := by
- simp [isLt]; omega
-theorem Nat.le_eq_false_of_lo (u v k : Nat) : isLt 0 k = true → u + k ≤ v → (v ≤ u) = False := by
- simp [isLt]; omega
-theorem Nat.lo_eq_false_of_lo (u v k₁ k₂ : Nat) : isLt 0 (k₁+k₂) = true → u + k₁ ≤ v → (v + k₂ ≤ u) = False := by
-  simp [isLt]; omega
-theorem Nat.ro_eq_false_of_lo (u v k₁ k₂ : Nat) : isLt k₂ k₁ = true → u + k₁ ≤ v → (v ≤ u + k₂) = False := by
-  simp [isLt]; omega
-theorem Nat.lo_eq_false_of_ro (u v k₁ k₂ : Nat) : isLt k₁ k₂ = true → u ≤ v + k₁ → (v + k₂ ≤ u) = False := by
-  simp [isLt]; omega
-
-/-!
-Helper theorems for equality propagation
-/
-
-theorem Nat.le_of_eq_1 (u v : Nat) : u = v → u ≤ v := by omega
-theorem Nat.le_of_eq_2 (u v : Nat) : u = v → v ≤ u := by omega
-theorem Nat.eq_of_le_of_le (u v : Nat) : u ≤ v → v ≤ u → u = v := by omega
-theorem Nat.le_offset (a k : Nat) : k ≤ a + k := by omega
-
-end Lean.Grind
--- a/src/Init/Grind/PP.lean
+++ b/src/Init/Grind/PP.lean
@@ -1,30 +0,0 @@
-/-
-Copyright (c) 2024 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Init.NotationExtra
-
-namespace Lean.Grind
-/-!
-This is a hackish module for hovering node information in the `grind` tactic state.
-/
-
-inductive NodeDef where
-  | unit
-
-set_option linter.unusedVariables false in
-def node_def (_ : Nat) {α : Sort u} {a : α} : NodeDef := .unit
-
-@[app_unexpander node_def]
-def nodeDefUnexpander : PrettyPrinter.Unexpander := fun stx => do
-  match stx with
-  | `($_ $id:num) => return mkIdent <| Name.mkSimple $ "#" ++ toString id.getNat
-  | _ => throw ()
-
-@[app_unexpander NodeDef]
-def NodeDefUnexpander : PrettyPrinter.Unexpander := fun _ => do
-  return mkIdent <| Name.mkSimple "NodeDef"
-
-end Lean.Grind
--- a/src/Init/Grind/Tactics.lean
+++ b/src/Init/Grind/Tactics.lean
@@ -25,7 +25,7 @@ Passed to `grind` using, for example, the `grind (config := { matchEqs := true }
 -/
 structure Config where
  /-- Maximum number of case-splits in a proof search branch. It does not include splits performed during normalization. -/
-  splits : Nat := 8
+  splits : Nat := 5
  /-- Maximum number of E-matching (aka heuristic theorem instantiation) rounds before each case split. -/
  ematch : Nat := 5
  /--
@@ -37,14 +37,6 @@ structure Config where
  instances : Nat := 1000
  /-- If `matchEqs` is `true`, `grind` uses `match`-equations as E-matching theorems. -/
  matchEqs : Bool := true
-  /-- If `splitMatch` is `true`, `grind` performs case-splitting on `match`-expressions during the search. -/
-  splitMatch : Bool := true
-  /-- If `splitIte` is `true`, `grind` performs case-splitting on `if-then-else` expressions during the search. -/
-  splitIte : Bool := true
-  /--
-  If `splitIndPred` is `true`, `grind` performs case-splitting on inductive predicates.
-  Otherwise, it performs case-splitting only on types marked with `[grind_split]` attribute. -/
-  splitIndPred : Bool := true
  deriving Inhabited, BEq

 end Lean.Grind
--- a/src/Init/Grind/Util.lean
+++ b/src/Init/Grind/Util.lean
@@ -9,7 +9,7 @@ import Init.Core
 namespace Lean.Grind

 /-- A helper gadget for annotating nested proofs in goals. -/
-def nestedProof (p : Prop) {h : p} : p := h
+def nestedProof (p : Prop) (h : p) : p := h

 /--
 Gadget for marking terms that should not be normalized by `grind`s simplifier.
@@ -28,7 +28,7 @@ When `EqMatch a b origin` is `True`, we mark `origin` as a resolved case-split.
 -/
 def EqMatch (a b : α) {_origin : α} : Prop := a = b

-theorem nestedProof_congr (p q : Prop) (h : p = q) (hp : p) (hq : q) : HEq (@nestedProof p hp) (@nestedProof q hq) := by
+theorem nestedProof_congr (p q : Prop) (h : p = q) (hp : p) (hq : q) : HEq (nestedProof p hp) (nestedProof q hq) := by
  subst h; apply HEq.refl

 end Lean.Grind
--- a/src/Lean/AddDecl.lean
+++ b/src/Lean/AddDecl.lean
@@ -21,6 +21,11 @@ def Environment.addDecl (env : Environment) (opts : Options) (decl : Declaration
  else
    addDeclCore env (Core.getMaxHeartbeats opts).toUSize decl cancelTk?

+def Environment.addAndCompile (env : Environment) (opts : Options) (decl : Declaration)
+    (cancelTk? : Option IO.CancelToken := none) : Except KernelException Environment := do
+  let env ← addDecl env opts decl cancelTk?
+  compileDecl env opts decl
+
 def addDecl (decl : Declaration) : CoreM Unit := do
  profileitM Exception "type checking" (← getOptions) do
    withTraceNode `Kernel (fun _ => return m!"typechecking declaration") do
--- a/src/Lean/Compiler/InitAttr.lean
+++ b/src/Lean/Compiler/InitAttr.lean
@@ -144,7 +144,11 @@ def declareBuiltin (forDecl : Name) (value : Expr) : CoreM Unit := do
  let type := mkApp (mkConst `IO) (mkConst `Unit)
  let decl := Declaration.defnDecl { name, levelParams := [], type, value, hints := ReducibilityHints.opaque,
                                     safety := DefinitionSafety.safe }
-  addAndCompile decl
-  IO.ofExcept (setBuiltinInitAttr (← getEnv) name) >>= setEnv
+  match (← getEnv).addAndCompile {} decl with
+  -- TODO: pretty print error
+  | Except.error e => do
+    let msg ← (e.toMessageData {}).toString
+    throwError "failed to emit registration code for builtin '{forDecl}': {msg}"
+  | Except.ok env  => IO.ofExcept (setBuiltinInitAttr env name) >>= setEnv

 end Lean
--- a/src/Lean/Compiler/LCNF/MonoTypes.lean
+++ b/src/Lean/Compiler/LCNF/MonoTypes.lean
@@ -74,6 +74,8 @@ partial def toMonoType (type : Expr) : CoreM Expr := do
  let type := type.headBeta
  if type.isErased then
    return erasedExpr
+  else if type.isErased then
+    return erasedExpr
  else if isTypeFormerType type then
    return erasedExpr
  else match type with
--- a/src/Lean/Compiler/Old.lean
+++ b/src/Lean/Compiler/Old.lean
@@ -53,3 +53,18 @@ def isUnsafeRecName? : Name → Option Name
  | _ => none

 end Compiler
+
+namespace Environment
+
+/--
+Compile the given block of mutual declarations.
+Assumes the declarations have already been added to the environment using `addDecl`.
+-/
+@[extern "lean_compile_decls"]
+opaque compileDecls (env : Environment) (opt : @& Options) (decls : @& List Name) : Except KernelException Environment
+
+/-- Compile the given declaration, it assumes the declaration has already been added to the environment using `addDecl`. -/
+def compileDecl (env : Environment) (opt : @& Options) (decl : @& Declaration) : Except KernelException Environment :=
+  compileDecls env opt (Compiler.getDeclNamesForCodeGen decl)
+
+end Environment
--- a/src/Lean/CoreM.lean
+++ b/src/Lean/CoreM.lean
@@ -514,16 +514,13 @@ register_builtin_option compiler.enableNew : Bool := {
@[extern "lean_lcnf_compile_decls"]
 opaque compileDeclsNew (declNames : List Name) : CoreM Unit

-@[extern "lean_compile_decls"]
-opaque compileDeclsOld (env : Environment) (opt : @& Options) (decls : @& List Name) : Except KernelException Environment
-
 def compileDecl (decl : Declaration) : CoreM Unit := do
  let opts ← getOptions
  let decls := Compiler.getDeclNamesForCodeGen decl
  if compiler.enableNew.get opts then
    compileDeclsNew decls
  let res ← withTraceNode `compiler (fun _ => return m!"compiling old: {decls}") do
-    return compileDeclsOld (← getEnv) opts decls
+    return (← getEnv).compileDecl opts decl
  match res with
  | Except.ok env => setEnv env
  | Except.error (KernelException.other msg) =>
@@ -536,7 +533,7 @@ def compileDecls (decls : List Name) : CoreM Unit := do
  let opts ← getOptions
  if compiler.enableNew.get opts then
    compileDeclsNew decls
-  match compileDeclsOld (← getEnv) opts decls with
+  match (← getEnv).compileDecls opts decls with
  | Except.ok env   => setEnv env
  | Except.error (KernelException.other msg) =>
    throwError msg
--- a/src/Lean/Data/AssocList.lean
+++ b/src/Lean/Data/AssocList.lean
@@ -24,7 +24,7 @@ abbrev empty : AssocList α β :=

 instance : EmptyCollection (AssocList α β) := ⟨empty⟩

-abbrev insertNew (m : AssocList α β) (k : α) (v : β) : AssocList α β :=
+abbrev insert (m : AssocList α β) (k : α) (v : β) : AssocList α β :=
  m.cons k v

 def isEmpty : AssocList α β → Bool
@@ -77,12 +77,6 @@ def replace [BEq α] (a : α) (b : β) : AssocList α β → AssocList α β
    | true  => cons a b es
    | false => cons k v (replace a b es)

-def insert [BEq α] (m : AssocList α β) (k : α) (v : β) : AssocList α β :=
-  if m.contains k then
-    m.replace k v
-  else
-    m.insertNew k v
-
 def erase [BEq α] (a : α) : AssocList α β → AssocList α β
  | nil         => nil
  | cons k v es => match k == a with
--- a/src/Lean/Elab/App.lean
+++ b/src/Lean/Elab/App.lean
@@ -1474,7 +1474,7 @@ where
    | field::fields, false => .fieldName field field.getId.getString! none fIdent :: toLVals fields false

 /-- Resolve `(.$id:ident)` using the expected type to infer namespace. -/
-private partial def resolveDotName (id : Syntax) (expectedType? : Option Expr) : TermElabM Expr := do
+private partial def resolveDotName (id : Syntax) (expectedType? : Option Expr) : TermElabM Name := do
  tryPostponeIfNoneOrMVar expectedType?
  let some expectedType := expectedType?
    | throwError "invalid dotted identifier notation, expected type must be known"
@@ -1489,7 +1489,7 @@ where
        withForallBody body k
      else
        k body
-  go (resultType : Expr) (expectedType : Expr) (previousExceptions : Array Exception) : TermElabM Expr := do
+  go (resultType : Expr) (expectedType : Expr) (previousExceptions : Array Exception) : TermElabM Name := do
    let resultType ← instantiateMVars resultType
    let resultTypeFn := resultType.cleanupAnnotations.getAppFn
    try
@@ -1497,12 +1497,9 @@ where
      let .const declName .. := resultTypeFn.cleanupAnnotations
        | throwError "invalid dotted identifier notation, expected type is not of the form (... → C ...) where C is a constant{indentExpr expectedType}"
      let idNew := declName ++ id.getId.eraseMacroScopes
-      if (← getEnv).contains idNew then
-        mkConst idNew
-      else if let some (fvar, []) ← resolveLocalName idNew then
-        return fvar
-      else
+      unless (← getEnv).contains idNew do
        throwError "invalid dotted identifier notation, unknown identifier `{idNew}` from expected type{indentExpr expectedType}"
+      return idNew
    catch
      | ex@(.error ..) =>
        match (← unfoldDefinition? resultType) with
@@ -1551,7 +1548,7 @@ private partial def elabAppFn (f : Syntax) (lvals : List LVal) (namedArgs : Arra
    | `(_)       => throwError "placeholders '_' cannot be used where a function is expected"
    | `(.$id:ident) =>
        addCompletionInfo <| CompletionInfo.dotId f id.getId (← getLCtx) expectedType?
-        let fConst ← resolveDotName id expectedType?
+        let fConst ← mkConst (← resolveDotName id expectedType?)
        let s ← observing do
          -- Use (force := true) because we want to record the result of .ident resolution even in patterns
          let fConst ← addTermInfo f fConst expectedType? (force := true)
--- a/src/Lean/Elab/Import.lean
+++ b/src/Lean/Elab/Import.lean
@@ -5,7 +5,7 @@ Authors: Leonardo de Moura, Sebastian Ullrich
 -/
 prelude
 import Lean.Parser.Module
-import Lean.Util.Paths
+import Lean.Data.Json

 namespace Lean.Elab

@@ -42,12 +42,4 @@ def printImports (input : String) (fileName : Option String) : IO Unit := do
    let fname ← findOLean dep.module
    IO.println fname

-@[export lean_print_import_srcs]
-def printImportSrcs (input : String) (fileName : Option String) : IO Unit := do
-  let sp ← initSrcSearchPath
-  let (deps, _, _) ← parseImports input fileName
-  for dep in deps do
-    let fname ← findLean sp dep.module
-    IO.println fname
-
 end Lean.Elab
--- a/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize.lean
+++ b/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize.lean
@@ -4,28 +4,342 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Henrik Böving
 -/
 prelude
+import Lean.Meta.AppBuilder
+import Lean.Meta.Tactic.AC.Main
+import Lean.Elab.Tactic.Simp
 import Lean.Elab.Tactic.FalseOrByContra
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.Basic
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.Simproc
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.Rewrite
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.AndFlatten
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.EmbeddedConstraint
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.AC
+import Lean.Elab.Tactic.BVDecide.Frontend.Attr
+import Std.Tactic.BVDecide.Normalize
+import Std.Tactic.BVDecide.Syntax

 /-!
-This module contains the implementation of `bv_normalize`, the preprocessing tactic for `bv_decide`.
-It is in essence a (slightly reduced) version of the Bitwuzla preprocessor together with Lean
-specific details.
+This module contains the implementation of `bv_normalize` which is effectively a custom `bv_normalize`
+simp set that is called like this: `simp only [seval, bv_normalize]`. The rules in `bv_normalize`
+fulfill two goals:
+1. Turn all hypothesis involving `Bool` and `BitVec` into the form `x = true` where `x` only consists
+   of a operations on `Bool` and `BitVec`. In particular no `Prop` should be contained. This makes
+   the reflection procedure further down the pipeline much easier to implement.
+2. Apply simplification rules from the Bitwuzla SMT solver.
 -/

 namespace Lean.Elab.Tactic.BVDecide
 namespace Frontend.Normalize

 open Lean.Meta
+open Std.Tactic.BVDecide.Normalize

-def passPipeline : PreProcessM (List Pass) := do
-  let mut passPipeline := [rewriteRulesPass]
-  let cfg ← PreProcessM.getConfig
+builtin_simproc ↓ [bv_normalize] reduceCond (cond _ _ _) := fun e => do
+  let_expr f@cond α c tb eb := e | return .continue
+  let r ← Simp.simp c
+  if r.expr.cleanupAnnotations.isConstOf ``Bool.true then
+    let pr := mkApp (mkApp4 (mkConst ``Bool.cond_pos f.constLevels!) α c tb eb) (← r.getProof)
+    return .visit { expr := tb, proof? := pr }
+  else if r.expr.cleanupAnnotations.isConstOf ``Bool.false then
+    let pr := mkApp (mkApp4 (mkConst ``Bool.cond_neg f.constLevels!) α c tb eb) (← r.getProof)
+    return .visit { expr := eb, proof? := pr }
+  else
+    return .continue
+
+builtin_simproc [bv_normalize] eqToBEq (((_ : Bool) = (_ : Bool))) := fun e => do
+  let_expr Eq _ lhs rhs := e | return .continue
+  match_expr rhs with
+  | Bool.true => return .continue
+  | _ =>
+    let beqApp ← mkAppM ``BEq.beq #[lhs, rhs]
+    let new := mkApp3 (mkConst ``Eq [1]) (mkConst ``Bool) beqApp (mkConst ``Bool.true)
+    let proof := mkApp2 (mkConst ``Bool.eq_to_beq) lhs rhs
+    return .done { expr := new, proof? := some proof }
+
+builtin_simproc [bv_normalize] andOnes ((_ : BitVec _) &&& (_ : BitVec _)) := fun e => do
+  let_expr HAnd.hAnd _ _ _ _ lhs rhs := e | return .continue
+  let some ⟨w, rhsValue⟩ ← getBitVecValue? rhs | return .continue
+  if rhsValue == -1#w then
+    let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.and_ones) (toExpr w) lhs
+    return .visit { expr := lhs, proof? := some proof }
+  else
+    return .continue
+
+builtin_simproc [bv_normalize] onesAnd ((_ : BitVec _) &&& (_ : BitVec _)) := fun e => do
+  let_expr HAnd.hAnd _ _ _ _ lhs rhs := e | return .continue
+  let some ⟨w, lhsValue⟩ ← getBitVecValue? lhs | return .continue
+  if lhsValue == -1#w then
+    let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.ones_and) (toExpr w) rhs
+    return .visit { expr := rhs, proof? := some proof }
+  else
+    return .continue
+
+builtin_simproc [bv_normalize] maxUlt (BitVec.ult (_ : BitVec _) (_ : BitVec _)) := fun e => do
+  let_expr BitVec.ult _ lhs rhs := e | return .continue
+  let some ⟨w, lhsValue⟩ ← getBitVecValue? lhs | return .continue
+  if lhsValue == -1#w then
+    let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.max_ult') (toExpr w) rhs
+    return .visit { expr := toExpr Bool.false, proof? := some proof }
+  else
+    return .continue
+
+-- A specialised version of BitVec.neg_eq_not_add so it doesn't trigger on -constant
+builtin_simproc [bv_normalize] neg_eq_not_add (-(_ : BitVec _)) := fun e => do
+  let_expr Neg.neg typ _ val := e | return .continue
+  let_expr BitVec widthExpr := typ | return .continue
+  let some w ← getNatValue? widthExpr | return .continue
+  match ← getBitVecValue? val with
+  | some _ => return .continue
+  | none =>
+    let proof := mkApp2 (mkConst ``BitVec.neg_eq_not_add) (toExpr w) val
+    let expr ← mkAppM ``HAdd.hAdd #[← mkAppM ``Complement.complement #[val], (toExpr 1#w)]
+    return .visit { expr := expr, proof? := some proof }
+
+builtin_simproc [bv_normalize] bv_add_const ((_ : BitVec _) + ((_ : BitVec _) + (_ : BitVec _))) :=
+  fun e => do
+    let_expr HAdd.hAdd _ _ _ _ exp1 rhs := e | return .continue
+    let_expr HAdd.hAdd _ _ _ _ exp2 exp3 := rhs | return .continue
+    let some ⟨w, exp1Val⟩ ←  getBitVecValue? exp1 | return .continue
+    let proofBuilder thm := mkApp4 (mkConst thm) (toExpr w) exp1 exp2 exp3
+    match ← getBitVecValue? exp2 with
+    | some ⟨w', exp2Val⟩ =>
+      if h : w = w' then
+        let newLhs := exp1Val + h ▸ exp2Val
+        let expr ← mkAppM ``HAdd.hAdd #[toExpr newLhs, exp3]
+        let proof := proofBuilder ``Std.Tactic.BVDecide.Normalize.BitVec.add_const_left
+        return .visit { expr := expr, proof? := some proof }
+      else
+        return .continue
+    | none =>
+      let some ⟨w', exp3Val⟩ ← getBitVecValue? exp3 | return .continue
+      if h : w = w' then
+        let newLhs := exp1Val + h ▸ exp3Val
+        let expr ← mkAppM ``HAdd.hAdd #[toExpr newLhs, exp2]
+        let proof := proofBuilder ``Std.Tactic.BVDecide.Normalize.BitVec.add_const_right
+        return .visit { expr := expr, proof? := some proof }
+      else
+        return .continue
+
+builtin_simproc [bv_normalize] bv_add_const' (((_ : BitVec _) + (_ : BitVec _)) + (_ : BitVec _)) :=
+  fun e => do
+    let_expr HAdd.hAdd _ _ _ _ lhs exp3 := e | return .continue
+    let_expr HAdd.hAdd _ _ _ _ exp1 exp2 := lhs | return .continue
+    let some ⟨w, exp3Val⟩ ←  getBitVecValue? exp3 | return .continue
+    let proofBuilder thm := mkApp4 (mkConst thm) (toExpr w) exp1 exp2 exp3
+    match ← getBitVecValue? exp1 with
+    | some ⟨w', exp1Val⟩ =>
+      if h : w = w' then
+        let newLhs := exp3Val + h ▸ exp1Val
+        let expr ← mkAppM ``HAdd.hAdd #[toExpr newLhs, exp2]
+        let proof := proofBuilder ``Std.Tactic.BVDecide.Normalize.BitVec.add_const_left'
+        return .visit { expr := expr, proof? := some proof }
+      else
+        return .continue
+    | none =>
+      let some ⟨w', exp2Val⟩ ← getBitVecValue? exp2 | return .continue
+      if h : w = w' then
+        let newLhs := exp3Val + h ▸ exp2Val
+        let expr ← mkAppM ``HAdd.hAdd #[toExpr newLhs, exp1]
+        let proof := proofBuilder ``Std.Tactic.BVDecide.Normalize.BitVec.add_const_right'
+        return .visit { expr := expr, proof? := some proof }
+      else
+        return .continue
+
+/-- Return a number `k` such that `2^k = n`. -/
+private def Nat.log2Exact (n : Nat) : Option Nat := do
+  guard <| n ≠ 0
+  let k := n.log2
+  guard <| Nat.pow 2 k == n
+  return k
+
+-- Build an expression for `x ^ y`.
+def mkPow (x y : Expr) : MetaM Expr := mkAppM ``HPow.hPow #[x, y]
+
+builtin_simproc [bv_normalize] bv_udiv_of_two_pow (((_ : BitVec _) / (BitVec.ofNat _ _) : BitVec _)) := fun e => do
+  let_expr HDiv.hDiv _α _β _γ _self x y := e | return .continue
+  let some ⟨w, yVal⟩ ← getBitVecValue? y | return .continue
+  let n := yVal.toNat
+  -- BitVec.ofNat w n, where n =def= 2^k
+  let some k := Nat.log2Exact n | return .continue
+  -- check that k < w.
+  if k ≥ w then return .continue
+  let rhs ← mkAppM ``HShiftRight.hShiftRight #[x, mkNatLit k]
+  -- 2^k = n
+  let hk ← mkDecideProof (← mkEq (← mkPow (mkNatLit 2) (mkNatLit k)) (mkNatLit n))
+  -- k < w
+  let hlt ← mkDecideProof (← mkLt (mkNatLit k) (mkNatLit w))
+  let proof := mkAppN (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.udiv_ofNat_eq_of_lt)
+    #[mkNatLit w, x, mkNatLit n, mkNatLit k, hk, hlt]
+  return .done {
+      expr :=  rhs
+      proof? := some proof
+  }
+
+/--
+A pass in the normalization pipeline. Takes the current goal and produces a refined one or closes
+the goal fully, indicated by returning `none`.
+-/
+structure Pass where
+  name : Name
+  run : MVarId → MetaM (Option MVarId)
+
+namespace Pass
+
+/--
+Repeatedly run a list of `Pass` until they either close the goal or an iteration doesn't change
+the goal anymore.
+-/
+partial def fixpointPipeline (passes : List Pass) (goal : MVarId) : MetaM (Option MVarId) := do
+  let runPass (goal? : Option MVarId) (pass : Pass) : MetaM (Option MVarId) := do
+    let some goal := goal? | return none
+    withTraceNode `bv (fun _ => return s!"Running pass: {pass.name}") do
+      pass.run goal
+
+  let some newGoal := ← passes.foldlM (init := some goal) runPass | return none
+  if goal != newGoal then
+    trace[Meta.Tactic.bv] m!"Rerunning pipeline on:\n{newGoal}"
+    fixpointPipeline passes newGoal
+  else
+    trace[Meta.Tactic.bv] "Pipeline reached a fixpoint"
+    return newGoal
+
+/--
+Responsible for applying the Bitwuzla style rewrite rules.
+-/
+def rewriteRulesPass (maxSteps : Nat) : Pass where
+  name := `rewriteRules
+  run goal := do
+    let bvThms ← bvNormalizeExt.getTheorems
+    let bvSimprocs ← bvNormalizeSimprocExt.getSimprocs
+    let sevalThms ← getSEvalTheorems
+    let sevalSimprocs ← Simp.getSEvalSimprocs
+
+    let simpCtx ← Simp.mkContext
+      (config := { failIfUnchanged := false, zetaDelta := true, maxSteps })
+      (simpTheorems := #[bvThms, sevalThms])
+      (congrTheorems := (← getSimpCongrTheorems))
+
+    let hyps ← goal.getNondepPropHyps
+    let ⟨result?, _⟩ ← simpGoal goal
+      (ctx := simpCtx)
+      (simprocs := #[bvSimprocs, sevalSimprocs])
+      (fvarIdsToSimp := hyps)
+    let some (_, newGoal) := result? | return none
+    return newGoal
+
+/--
+Flatten out ands. That is look for hypotheses of the form `h : (x && y) = true` and replace them
+with `h.left : x = true` and `h.right : y = true`. This can enable more fine grained substitutions
+in embedded constraint substitution.
+-/
+partial def andFlatteningPass : Pass where
+  name := `andFlattening
+  run goal := do
+    goal.withContext do
+      let hyps ← goal.getNondepPropHyps
+      let mut newHyps := #[]
+      let mut oldHyps := #[]
+      for fvar in hyps do
+        let hyp : Hypothesis := {
+          userName := (← fvar.getDecl).userName
+          type := ← fvar.getType
+          value := mkFVar fvar
+        }
+        let sizeBefore := newHyps.size
+        newHyps ← splitAnds hyp newHyps
+        if newHyps.size > sizeBefore then
+          oldHyps := oldHyps.push fvar
+      if newHyps.size == 0 then
+        return goal
+      else
+        let (_, goal) ← goal.assertHypotheses newHyps
+        -- Given that we collected the hypotheses in the correct order above the invariant is given
+        let goal ← goal.tryClearMany oldHyps
+        return goal
+where
+  splitAnds (hyp : Hypothesis) (hyps : Array Hypothesis) (first : Bool := true) :
+      MetaM (Array Hypothesis) := do
+    match ← trySplit hyp with
+    | some (left, right) =>
+      let hyps ← splitAnds left hyps false
+      splitAnds right hyps false
+    | none =>
+      if first then
+        return hyps
+      else
+        return hyps.push hyp
+
+  trySplit (hyp : Hypothesis) : MetaM (Option (Hypothesis × Hypothesis)) := do
+    let typ := hyp.type
+    let_expr Eq α eqLhs eqRhs := typ | return none
+    let_expr Bool.and lhs rhs := eqLhs | return none
+    let_expr Bool.true := eqRhs | return none
+    let_expr Bool := α | return none
+    let mkEqTrue (lhs : Expr) : Expr :=
+      mkApp3 (mkConst ``Eq [1]) (mkConst ``Bool) lhs (mkConst ``Bool.true)
+    let leftHyp : Hypothesis := {
+      userName := hyp.userName,
+      type := mkEqTrue lhs,
+      value := mkApp3 (mkConst ``Std.Tactic.BVDecide.Normalize.Bool.and_left) lhs rhs hyp.value
+    }
+    let rightHyp : Hypothesis := {
+      userName := hyp.userName,
+      type := mkEqTrue rhs,
+      value := mkApp3 (mkConst ``Std.Tactic.BVDecide.Normalize.Bool.and_right) lhs rhs hyp.value
+    }
+    return some (leftHyp, rightHyp)
+
+/--
+Substitute embedded constraints. That is look for hypotheses of the form `h : x = true` and use
+them to substitute occurences of `x` within other hypotheses. Additionally this drops all
+redundant top level hypotheses.
+-/
+def embeddedConstraintPass (maxSteps : Nat) : Pass where
+  name := `embeddedConstraintSubsitution
+  run goal := do
+    goal.withContext do
+      let hyps ← goal.getNondepPropHyps
+      let mut relevantHyps : SimpTheoremsArray := #[]
+      let mut seen : Std.HashSet Expr := {}
+      let mut duplicates : Array FVarId := #[]
+      for hyp in hyps do
+        let typ ← hyp.getType
+        let_expr Eq α lhs rhs := typ | continue
+        let_expr Bool.true := rhs | continue
+        let_expr Bool := α | continue
+        if seen.contains lhs then
+          -- collect and later remove duplicates on the fly
+          duplicates := duplicates.push hyp
+        else
+          seen := seen.insert lhs
+          let localDecl ← hyp.getDecl
+          let proof  := localDecl.toExpr
+          relevantHyps ← relevantHyps.addTheorem (.fvar hyp) proof
+
+      let goal ← goal.tryClearMany duplicates
+
+      let simpCtx ← Simp.mkContext
+        (config := { failIfUnchanged := false, maxSteps })
+        (simpTheorems := relevantHyps)
+        (congrTheorems := (← getSimpCongrTheorems))
+
+      let ⟨result?, _⟩ ← simpGoal goal (ctx := simpCtx) (fvarIdsToSimp := ← goal.getNondepPropHyps)
+      let some (_, newGoal) := result? | return none
+      return newGoal
+
+/--
+Normalize with respect to Associativity and Commutativity.
+-/
+def acNormalizePass : Pass where
+  name := `ac_nf
+  run goal := do
+    let mut newGoal := goal
+    for hyp in (← goal.getNondepPropHyps) do
+      let result ← Lean.Meta.AC.acNfHypMeta newGoal hyp
+
+      if let .some nextGoal := result then
+        newGoal := nextGoal
+      else
+        return none
+
+    return newGoal
+
+def passPipeline (cfg : BVDecideConfig) : List Pass := Id.run do
+  let mut passPipeline := [rewriteRulesPass cfg.maxSteps]

  if cfg.acNf then
    passPipeline := passPipeline ++ [acNormalizePass]
@@ -34,20 +348,18 @@ def passPipeline : PreProcessM (List Pass) := do
    passPipeline := passPipeline ++ [andFlatteningPass]

  if cfg.embeddedConstraintSubst then
-    passPipeline := passPipeline ++ [embeddedConstraintPass]
+    passPipeline := passPipeline ++ [embeddedConstraintPass cfg.maxSteps]

  return passPipeline

-def bvNormalize (g : MVarId) (cfg : BVDecideConfig) : MetaM (Option MVarId) := do
-  withTraceNode `bv (fun _ => return "Preprocessing goal") do
-    (go g).run cfg
-where
-  go (g : MVarId) : PreProcessM (Option MVarId) := do
-    let some g ← g.falseOrByContra | return none
+end Pass

+def bvNormalize (g : MVarId) (cfg : BVDecideConfig) : MetaM (Option MVarId) := do
+  withTraceNode `bv (fun _ => return "Normalizing goal") do
+    -- Contradiction proof
+    let some g ← g.falseOrByContra | return none
    trace[Meta.Tactic.bv] m!"Running preprocessing pipeline on:\n{g}"
-    let pipeline ← passPipeline
-    Pass.fixpointPipeline pipeline g
+    Pass.fixpointPipeline (Pass.passPipeline cfg) g

@[builtin_tactic Lean.Parser.Tactic.bvNormalize]
 def evalBVNormalize : Tactic := fun
--- a/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/AC.lean
+++ b/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/AC.lean
@@ -1,39 +0,0 @@
-/-
-Copyright (c) 2025 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.Basic
-import Lean.Meta.Tactic.AC.Main
-
-/-!
-This module contains the implementation of the associativity and commutativity normalisation pass
-in the fixpoint pipeline.
-/
-
-namespace Lean.Elab.Tactic.BVDecide
-namespace Frontend.Normalize
-
-open Lean.Meta
-
-/--
-Normalize with respect to Associativity and Commutativity.
-/
-def acNormalizePass : Pass where
-  name := `ac_nf
-  run' goal := do
-    let mut newGoal := goal
-    for hyp in (← goal.getNondepPropHyps) do
-      let result ← AC.acNfHypMeta newGoal hyp
-
-      if let .some nextGoal := result then
-        newGoal := nextGoal
-      else
-        return none
-
-    return newGoal
-
-
-end Frontend.Normalize
-end Lean.Elab.Tactic.BVDecide
--- a/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/AndFlatten.lean
+++ b/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/AndFlatten.lean
@@ -1,86 +0,0 @@
-/-
-Copyright (c) 2025 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Std.Tactic.BVDecide.Normalize.Bool
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.Basic
-import Lean.Meta.Tactic.Assert
-
-/-!
-This module contains the implementation of the and flattening pass in the fixpoint pipeline, taking
-hypotheses of the form `h : x && y = true` and splitting them into `h1 : x = true` and
-`h2 : y = true` recursively.
-/
-
-namespace Lean.Elab.Tactic.BVDecide
-namespace Frontend.Normalize
-
-open Lean.Meta
-
-/--
-Flatten out ands. That is look for hypotheses of the form `h : (x && y) = true` and replace them
-with `h.left : x = true` and `h.right : y = true`. This can enable more fine grained substitutions
-in embedded constraint substitution.
-/
-partial def andFlatteningPass : Pass where
-  name := `andFlattening
-  run' goal := do
-    goal.withContext do
-      let hyps ← goal.getNondepPropHyps
-      let mut newHyps := #[]
-      let mut oldHyps := #[]
-      for fvar in hyps do
-        let hyp : Hypothesis := {
-          userName := (← fvar.getDecl).userName
-          type := ← fvar.getType
-          value := mkFVar fvar
-        }
-        let sizeBefore := newHyps.size
-        newHyps ← splitAnds hyp newHyps
-        if newHyps.size > sizeBefore then
-          oldHyps := oldHyps.push fvar
-      if newHyps.size == 0 then
-        return goal
-      else
-        let (_, goal) ← goal.assertHypotheses newHyps
-        -- Given that we collected the hypotheses in the correct order above the invariant is given
-        let goal ← goal.tryClearMany oldHyps
-        return goal
-where
-  splitAnds (hyp : Hypothesis) (hyps : Array Hypothesis) (first : Bool := true) :
-      MetaM (Array Hypothesis) := do
-    match ← trySplit hyp with
-    | some (left, right) =>
-      let hyps ← splitAnds left hyps false
-      splitAnds right hyps false
-    | none =>
-      if first then
-        return hyps
-      else
-        return hyps.push hyp
-
-  trySplit (hyp : Hypothesis) : MetaM (Option (Hypothesis × Hypothesis)) := do
-    let typ := hyp.type
-    let_expr Eq α eqLhs eqRhs := typ | return none
-    let_expr Bool.and lhs rhs := eqLhs | return none
-    let_expr Bool.true := eqRhs | return none
-    let_expr Bool := α | return none
-    let mkEqTrue (lhs : Expr) : Expr :=
-      mkApp3 (mkConst ``Eq [1]) (mkConst ``Bool) lhs (mkConst ``Bool.true)
-    let leftHyp : Hypothesis := {
-      userName := hyp.userName,
-      type := mkEqTrue lhs,
-      value := mkApp3 (mkConst ``Std.Tactic.BVDecide.Normalize.Bool.and_left) lhs rhs hyp.value
-    }
-    let rightHyp : Hypothesis := {
-      userName := hyp.userName,
-      type := mkEqTrue rhs,
-      value := mkApp3 (mkConst ``Std.Tactic.BVDecide.Normalize.Bool.and_right) lhs rhs hyp.value
-    }
-    return some (leftHyp, rightHyp)
-
-
-end Frontend.Normalize
-end Lean.Elab.Tactic.BVDecide
--- a/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/Basic.lean
+++ b/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/Basic.lean
@@ -1,67 +0,0 @@
-/-
-Copyright (c) 2025 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Lean.Meta.Basic
-import Lean.Elab.Tactic.BVDecide.Frontend.Attr
-
-/-!
-This module contains the basic preprocessing pipeline framework for `bv_normalize`.
-/
-
-namespace Lean.Elab.Tactic.BVDecide
-namespace Frontend.Normalize
-
-open Lean.Meta
-
-abbrev PreProcessM : Type → Type := ReaderT BVDecideConfig MetaM
-
-namespace PreProcessM
-
-def getConfig : PreProcessM BVDecideConfig := read
-
-def run (cfg : BVDecideConfig) (x : PreProcessM α) : MetaM α :=
-  ReaderT.run x cfg
-
-end PreProcessM
-
-/--
-A pass in the normalization pipeline. Takes the current goal and produces a refined one or closes
-the goal fully, indicated by returning `none`.
-/
-structure Pass where
-  name : Name
-  run' : MVarId → PreProcessM (Option MVarId)
-
-namespace Pass
-
-def run (pass : Pass) (goal : MVarId) : PreProcessM (Option MVarId) := do
-  withTraceNode `bv (fun _ => return m!"Running pass: {pass.name} on\n{goal}") do
-    pass.run' goal
-
-/--
-Repeatedly run a list of `Pass` until they either close the goal or an iteration doesn't change
-the goal anymore.
-/
-partial def fixpointPipeline (passes : List Pass) (goal : MVarId) : PreProcessM (Option MVarId) := do
-  let mut newGoal := goal
-  for pass in passes do
-    if let some nextGoal ← pass.run newGoal then
-      newGoal := nextGoal
-    else
-      trace[Meta.Tactic.bv] "Fixpoint iteration solved the goal"
-      return none
-
-  if goal != newGoal then
-    trace[Meta.Tactic.bv] m!"Rerunning pipeline on:\n{newGoal}"
-    fixpointPipeline passes newGoal
-  else
-    trace[Meta.Tactic.bv] "Pipeline reached a fixpoint"
-    return newGoal
-
-end Pass
-
-end Frontend.Normalize
-end Lean.Elab.Tactic.BVDecide
--- a/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/EmbeddedConstraint.lean
+++ b/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/EmbeddedConstraint.lean
@@ -1,62 +0,0 @@
-/-
-Copyright (c) 2025 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Std.Tactic.BVDecide.Normalize.Bool
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.Basic
-import Lean.Meta.Tactic.Simp
-
-/-!
-This module contains the implementation of the embedded constraint substitution pass in the fixpoint
-pipeline, substituting hypotheses of the form `h : x = true` in other hypotheses.
-/
-
-namespace Lean.Elab.Tactic.BVDecide
-namespace Frontend.Normalize
-
-open Lean.Meta
-
-/--
-Substitute embedded constraints. That is look for hypotheses of the form `h : x = true` and use
-them to substitute occurences of `x` within other hypotheses. Additionally this drops all
-redundant top level hypotheses.
-/
-def embeddedConstraintPass : Pass where
-  name := `embeddedConstraintSubsitution
-  run' goal := do
-    goal.withContext do
-      let hyps ← goal.getNondepPropHyps
-      let mut relevantHyps : SimpTheoremsArray := #[]
-      let mut seen : Std.HashSet Expr := {}
-      let mut duplicates : Array FVarId := #[]
-      for hyp in hyps do
-        let typ ← hyp.getType
-        let_expr Eq α lhs rhs := typ | continue
-        let_expr Bool.true := rhs | continue
-        let_expr Bool := α | continue
-        if seen.contains lhs then
-          -- collect and later remove duplicates on the fly
-          duplicates := duplicates.push hyp
-        else
-          seen := seen.insert lhs
-          let localDecl ← hyp.getDecl
-          let proof  := localDecl.toExpr
-          relevantHyps ← relevantHyps.addTheorem (.fvar hyp) proof
-
-      let goal ← goal.tryClearMany duplicates
-      let cfg ← PreProcessM.getConfig
-
-      let simpCtx ← Simp.mkContext
-        (config := { failIfUnchanged := false, maxSteps := cfg.maxSteps })
-        (simpTheorems := relevantHyps)
-        (congrTheorems := (← getSimpCongrTheorems))
-
-      let ⟨result?, _⟩ ← simpGoal goal (ctx := simpCtx) (fvarIdsToSimp := ← goal.getNondepPropHyps)
-      let some (_, newGoal) := result? | return none
-      return newGoal
-
-
-end Frontend.Normalize
-end Lean.Elab.Tactic.BVDecide
--- a/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/Rewrite.lean
+++ b/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/Rewrite.lean
@@ -1,47 +0,0 @@
-/-
-Copyright (c) 2025 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Lean.Elab.Tactic.Simp
-import Lean.Elab.Tactic.BVDecide.Frontend.Normalize.Basic
-import Lean.Elab.Tactic.BVDecide.Frontend.Attr
-
-/-!
-This module contains the implementation of the rewriting pass in the fixpoint pipeline, applying
-rules from the `bv_normalize` simp set.
-/
-
-namespace Lean.Elab.Tactic.BVDecide
-namespace Frontend.Normalize
-
-open Lean.Meta
-
-/--
-Responsible for applying the Bitwuzla style rewrite rules.
-/
-def rewriteRulesPass : Pass where
-  name := `rewriteRules
-  run' goal := do
-    let bvThms ← bvNormalizeExt.getTheorems
-    let bvSimprocs ← bvNormalizeSimprocExt.getSimprocs
-    let sevalThms ← getSEvalTheorems
-    let sevalSimprocs ← Simp.getSEvalSimprocs
-    let cfg ← PreProcessM.getConfig
-
-    let simpCtx ← Simp.mkContext
-      (config := { failIfUnchanged := false, zetaDelta := true, maxSteps := cfg.maxSteps })
-      (simpTheorems := #[bvThms, sevalThms])
-      (congrTheorems := (← getSimpCongrTheorems))
-
-    let hyps ← goal.getNondepPropHyps
-    let ⟨result?, _⟩ ← simpGoal goal
-      (ctx := simpCtx)
-      (simprocs := #[bvSimprocs, sevalSimprocs])
-      (fvarIdsToSimp := hyps)
-    let some (_, newGoal) := result? | return none
-    return newGoal
-
-end Frontend.Normalize
-end Lean.Elab.Tactic.BVDecide
--- a/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/Simproc.lean
+++ b/src/Lean/Elab/Tactic/BVDecide/Frontend/Normalize/Simproc.lean
@@ -1,164 +0,0 @@
-/-
-Copyright (c) 2025 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Std.Tactic.BVDecide.Normalize
-import Std.Tactic.BVDecide.Syntax
-import Lean.Elab.Tactic.Simp
-import Lean.Elab.Tactic.BVDecide.Frontend.Attr
-
-/-!
-This module contains implementations of simprocs used in the `bv_normalize` simp set.
-/
-
-namespace Lean.Elab.Tactic.BVDecide
-namespace Frontend.Normalize
-
-open Lean.Meta
-open Std.Tactic.BVDecide.Normalize
-
-builtin_simproc ↓ [bv_normalize] reduceCond (cond _ _ _) := fun e => do
-  let_expr f@cond α c tb eb := e | return .continue
-  let r ← Simp.simp c
-  if r.expr.cleanupAnnotations.isConstOf ``Bool.true then
-    let pr := mkApp (mkApp4 (mkConst ``Bool.cond_pos f.constLevels!) α c tb eb) (← r.getProof)
-    return .visit { expr := tb, proof? := pr }
-  else if r.expr.cleanupAnnotations.isConstOf ``Bool.false then
-    let pr := mkApp (mkApp4 (mkConst ``Bool.cond_neg f.constLevels!) α c tb eb) (← r.getProof)
-    return .visit { expr := eb, proof? := pr }
-  else
-    return .continue
-
-builtin_simproc [bv_normalize] eqToBEq (((_ : Bool) = (_ : Bool))) := fun e => do
-  let_expr Eq _ lhs rhs := e | return .continue
-  match_expr rhs with
-  | Bool.true => return .continue
-  | _ =>
-    let beqApp ← mkAppM ``BEq.beq #[lhs, rhs]
-    let new := mkApp3 (mkConst ``Eq [1]) (mkConst ``Bool) beqApp (mkConst ``Bool.true)
-    let proof := mkApp2 (mkConst ``Bool.eq_to_beq) lhs rhs
-    return .done { expr := new, proof? := some proof }
-
-builtin_simproc [bv_normalize] andOnes ((_ : BitVec _) &&& (_ : BitVec _)) := fun e => do
-  let_expr HAnd.hAnd _ _ _ _ lhs rhs := e | return .continue
-  let some ⟨w, rhsValue⟩ ← getBitVecValue? rhs | return .continue
-  if rhsValue == -1#w then
-    let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.and_ones) (toExpr w) lhs
-    return .visit { expr := lhs, proof? := some proof }
-  else
-    return .continue
-
-builtin_simproc [bv_normalize] onesAnd ((_ : BitVec _) &&& (_ : BitVec _)) := fun e => do
-  let_expr HAnd.hAnd _ _ _ _ lhs rhs := e | return .continue
-  let some ⟨w, lhsValue⟩ ← getBitVecValue? lhs | return .continue
-  if lhsValue == -1#w then
-    let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.ones_and) (toExpr w) rhs
-    return .visit { expr := rhs, proof? := some proof }
-  else
-    return .continue
-
-builtin_simproc [bv_normalize] maxUlt (BitVec.ult (_ : BitVec _) (_ : BitVec _)) := fun e => do
-  let_expr BitVec.ult _ lhs rhs := e | return .continue
-  let some ⟨w, lhsValue⟩ ← getBitVecValue? lhs | return .continue
-  if lhsValue == -1#w then
-    let proof := mkApp2 (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.max_ult') (toExpr w) rhs
-    return .visit { expr := toExpr Bool.false, proof? := some proof }
-  else
-    return .continue
-
-- A specialised version of BitVec.neg_eq_not_add so it doesn't trigger on -constant
-builtin_simproc [bv_normalize] neg_eq_not_add (-(_ : BitVec _)) := fun e => do
-  let_expr Neg.neg typ _ val := e | return .continue
-  let_expr BitVec widthExpr := typ | return .continue
-  let some w ← getNatValue? widthExpr | return .continue
-  match ← getBitVecValue? val with
-  | some _ => return .continue
-  | none =>
-    let proof := mkApp2 (mkConst ``BitVec.neg_eq_not_add) (toExpr w) val
-    let expr ← mkAppM ``HAdd.hAdd #[← mkAppM ``Complement.complement #[val], (toExpr 1#w)]
-    return .visit { expr := expr, proof? := some proof }
-
-builtin_simproc [bv_normalize] bv_add_const ((_ : BitVec _) + ((_ : BitVec _) + (_ : BitVec _))) :=
-  fun e => do
-    let_expr HAdd.hAdd _ _ _ _ exp1 rhs := e | return .continue
-    let_expr HAdd.hAdd _ _ _ _ exp2 exp3 := rhs | return .continue
-    let some ⟨w, exp1Val⟩ ←  getBitVecValue? exp1 | return .continue
-    let proofBuilder thm := mkApp4 (mkConst thm) (toExpr w) exp1 exp2 exp3
-    match ← getBitVecValue? exp2 with
-    | some ⟨w', exp2Val⟩ =>
-      if h : w = w' then
-        let newLhs := exp1Val + h ▸ exp2Val
-        let expr ← mkAppM ``HAdd.hAdd #[toExpr newLhs, exp3]
-        let proof := proofBuilder ``Std.Tactic.BVDecide.Normalize.BitVec.add_const_left
-        return .visit { expr := expr, proof? := some proof }
-      else
-        return .continue
-    | none =>
-      let some ⟨w', exp3Val⟩ ← getBitVecValue? exp3 | return .continue
-      if h : w = w' then
-        let newLhs := exp1Val + h ▸ exp3Val
-        let expr ← mkAppM ``HAdd.hAdd #[toExpr newLhs, exp2]
-        let proof := proofBuilder ``Std.Tactic.BVDecide.Normalize.BitVec.add_const_right
-        return .visit { expr := expr, proof? := some proof }
-      else
-        return .continue
-
-builtin_simproc [bv_normalize] bv_add_const' (((_ : BitVec _) + (_ : BitVec _)) + (_ : BitVec _)) :=
-  fun e => do
-    let_expr HAdd.hAdd _ _ _ _ lhs exp3 := e | return .continue
-    let_expr HAdd.hAdd _ _ _ _ exp1 exp2 := lhs | return .continue
-    let some ⟨w, exp3Val⟩ ←  getBitVecValue? exp3 | return .continue
-    let proofBuilder thm := mkApp4 (mkConst thm) (toExpr w) exp1 exp2 exp3
-    match ← getBitVecValue? exp1 with
-    | some ⟨w', exp1Val⟩ =>
-      if h : w = w' then
-        let newLhs := exp3Val + h ▸ exp1Val
-        let expr ← mkAppM ``HAdd.hAdd #[toExpr newLhs, exp2]
-        let proof := proofBuilder ``Std.Tactic.BVDecide.Normalize.BitVec.add_const_left'
-        return .visit { expr := expr, proof? := some proof }
-      else
-        return .continue
-    | none =>
-      let some ⟨w', exp2Val⟩ ← getBitVecValue? exp2 | return .continue
-      if h : w = w' then
-        let newLhs := exp3Val + h ▸ exp2Val
-        let expr ← mkAppM ``HAdd.hAdd #[toExpr newLhs, exp1]
-        let proof := proofBuilder ``Std.Tactic.BVDecide.Normalize.BitVec.add_const_right'
-        return .visit { expr := expr, proof? := some proof }
-      else
-        return .continue
-
-/-- Return a number `k` such that `2^k = n`. -/
-private def Nat.log2Exact (n : Nat) : Option Nat := do
-  guard <| n ≠ 0
-  let k := n.log2
-  guard <| Nat.pow 2 k == n
-  return k
-
-- Build an expression for `x ^ y`.
-def mkPow (x y : Expr) : MetaM Expr := mkAppM ``HPow.hPow #[x, y]
-
-builtin_simproc [bv_normalize] bv_udiv_of_two_pow (((_ : BitVec _) / (BitVec.ofNat _ _) : BitVec _)) := fun e => do
-  let_expr HDiv.hDiv _α _β _γ _self x y := e | return .continue
-  let some ⟨w, yVal⟩ ← getBitVecValue? y | return .continue
-  let n := yVal.toNat
-  -- BitVec.ofNat w n, where n =def= 2^k
-  let some k := Nat.log2Exact n | return .continue
-  -- check that k < w.
-  if k ≥ w then return .continue
-  let rhs ← mkAppM ``HShiftRight.hShiftRight #[x, mkNatLit k]
-  -- 2^k = n
-  let hk ← mkDecideProof (← mkEq (← mkPow (mkNatLit 2) (mkNatLit k)) (mkNatLit n))
-  -- k < w
-  let hlt ← mkDecideProof (← mkLt (mkNatLit k) (mkNatLit w))
-  let proof := mkAppN (mkConst ``Std.Tactic.BVDecide.Normalize.BitVec.udiv_ofNat_eq_of_lt)
-    #[mkNatLit w, x, mkNatLit n, mkNatLit k, hk, hlt]
-  return .done {
-      expr :=  rhs
-      proof? := some proof
-  }
-
-end Frontend.Normalize
-end Lean.Elab.Tactic.BVDecide
--- a/src/Lean/Elab/Tactic/Conv/Simp.lean
+++ b/src/Lean/Elab/Tactic/Conv/Simp.lean
@@ -7,10 +7,9 @@ prelude
 import Lean.Elab.Tactic.Simp
 import Lean.Elab.Tactic.Split
 import Lean.Elab.Tactic.Conv.Basic
-import Lean.Elab.Tactic.SimpTrace

 namespace Lean.Elab.Tactic.Conv
-open Meta Tactic TryThis
+open Meta

 def applySimpResult (result : Simp.Result) : TacticM Unit := do
  if result.proof?.isNone then
@@ -24,19 +23,6 @@ def applySimpResult (result : Simp.Result) : TacticM Unit := do
  let (result, _) ← dischargeWrapper.with fun d? => simp lhs ctx (simprocs := simprocs) (discharge? := d?)
  applySimpResult result

-@[builtin_tactic Lean.Parser.Tactic.Conv.simpTrace] def evalSimpTrace : Tactic := fun stx => withMainContext do
-  match stx with
-  | `(conv| simp?%$tk $cfg:optConfig $(discharger)? $[only%$o]? $[[$args,*]]?) => do
-    let stx ← `(tactic| simp%$tk $cfg:optConfig $[$discharger]? $[only%$o]? $[[$args,*]]?)
-    let { ctx, simprocs, dischargeWrapper, .. } ← mkSimpContext stx (eraseLocal := false)
-    let lhs ← getLhs
-    let (result, stats) ← dischargeWrapper.with fun d? =>
-      simp lhs ctx (simprocs := simprocs) (discharge? := d?)
-    applySimpResult result
-    let stx ← mkSimpCallStx stx stats.usedTheorems
-    addSuggestion tk stx (origSpan? := ← getRef)
-  | _ => throwUnsupportedSyntax
-
@[builtin_tactic Lean.Parser.Tactic.Conv.simpMatch] def evalSimpMatch : Tactic := fun _ => withMainContext do
  applySimpResult (← Split.simpMatch (← getLhs))

@@ -44,15 +30,4 @@ def applySimpResult (result : Simp.Result) : TacticM Unit := do
  let { ctx, .. } ← mkSimpContext stx (eraseLocal := false) (kind := .dsimp)
  changeLhs (← Lean.Meta.dsimp (← getLhs) ctx).1

-@[builtin_tactic Lean.Parser.Tactic.Conv.dsimpTrace] def evalDSimpTrace : Tactic := fun stx => withMainContext do
-  match stx with
-  | `(conv| dsimp?%$tk $cfg:optConfig $[only%$o]? $[[$args,*]]?) =>
-    let stx ← `(tactic| dsimp%$tk $cfg:optConfig $[only%$o]? $[[$args,*]]?)
-    let { ctx, .. } ← mkSimpContext stx (eraseLocal := false) (kind := .dsimp)
-    let (result, stats) ← Lean.Meta.dsimp (← getLhs) ctx
-    changeLhs result
-    let stx ← mkSimpCallStx stx stats.usedTheorems
-    addSuggestion tk stx (origSpan? := ← getRef)
-  | _ => throwUnsupportedSyntax
-
 end Lean.Elab.Tactic.Conv
--- a/src/Lean/Elab/Tactic/Grind.lean
+++ b/src/Lean/Elab/Tactic/Grind.lean
@@ -35,9 +35,9 @@ def elabGrindPattern : CommandElab := fun stx => do
  | _ => throwUnsupportedSyntax

 def grind (mvarId : MVarId) (config : Grind.Config) (mainDeclName : Name) (fallback : Grind.Fallback) : MetaM Unit := do
-  let goals ← Grind.main mvarId config mainDeclName fallback
-  unless goals.isEmpty do
-    throwError "`grind` failed\n{← Grind.goalsToMessageData goals}"
+  let mvarIds ← Grind.main mvarId config mainDeclName fallback
+  unless mvarIds.isEmpty do
+    throwError "`grind` failed\n{goalsToMessageData mvarIds}"

 private def elabFallback (fallback? : Option Term) : TermElabM (Grind.GoalM Unit) := do
  let some fallback := fallback? | return (pure ())
--- a/src/Lean/Meta/AppBuilder.lean
+++ b/src/Lean/Meta/AppBuilder.lean
@@ -11,14 +11,14 @@ import Lean.Meta.DecLevel

 namespace Lean.Meta

-/-- Returns `id e` -/
+/-- Return `id e` -/
 def mkId (e : Expr) : MetaM Expr := do
  let type ← inferType e
  let u    ← getLevel type
  return mkApp2 (mkConst ``id [u]) type e

 /--
-  Given `e` s.t. `inferType e` is definitionally equal to `expectedType`, returns
+  Given `e` s.t. `inferType e` is definitionally equal to `expectedType`, return
  term `@id expectedType e`. -/
 def mkExpectedTypeHint (e : Expr) (expectedType : Expr) : MetaM Expr := do
  let u ← getLevel expectedType
@@ -38,13 +38,13 @@ def mkLetFun (x : Expr) (v : Expr) (e : Expr) : MetaM Expr := do
  let u2 ← getLevel ety
  return mkAppN (.const ``letFun [u1, u2]) #[α, β, v, f]

-/-- Returns `a = b`. -/
+/-- Return `a = b`. -/
 def mkEq (a b : Expr) : MetaM Expr := do
  let aType ← inferType a
  let u ← getLevel aType
  return mkApp3 (mkConst ``Eq [u]) aType a b

-/-- Returns `HEq a b`. -/
+/-- Return `HEq a b`. -/
 def mkHEq (a b : Expr) : MetaM Expr := do
  let aType ← inferType a
  let bType ← inferType b
@@ -52,7 +52,7 @@ def mkHEq (a b : Expr) : MetaM Expr := do
  return mkApp4 (mkConst ``HEq [u]) aType a bType b

 /--
-  If `a` and `b` have definitionally equal types, returns `Eq a b`, otherwise returns `HEq a b`.
+  If `a` and `b` have definitionally equal types, return `Eq a b`, otherwise return `HEq a b`.
 -/
 def mkEqHEq (a b : Expr) : MetaM Expr := do
  let aType ← inferType a
@@ -63,25 +63,25 @@ def mkEqHEq (a b : Expr) : MetaM Expr := do
  else
    return mkApp4 (mkConst ``HEq [u]) aType a bType b

-/-- Returns a proof of `a = a`. -/
+/-- Return a proof of `a = a`. -/
 def mkEqRefl (a : Expr) : MetaM Expr := do
  let aType ← inferType a
  let u ← getLevel aType
  return mkApp2 (mkConst ``Eq.refl [u]) aType a

-/-- Returns a proof of `HEq a a`. -/
+/-- Return a proof of `HEq a a`. -/
 def mkHEqRefl (a : Expr) : MetaM Expr := do
  let aType ← inferType a
  let u ← getLevel aType
  return mkApp2 (mkConst ``HEq.refl [u]) aType a

-/-- Given `hp : P` and `nhp : Not P`, returns an instance of type `e`. -/
+/-- Given `hp : P` and `nhp : Not P` returns an instance of type `e`. -/
 def mkAbsurd (e : Expr) (hp hnp : Expr) : MetaM Expr := do
  let p ← inferType hp
  let u ← getLevel e
  return mkApp4 (mkConst ``absurd [u]) p e hp hnp

-/-- Given `h : False`, returns an instance of type `e`. -/
+/-- Given `h : False`, return an instance of type `e`. -/
 def mkFalseElim (e : Expr) (h : Expr) : MetaM Expr := do
  let u ← getLevel e
  return mkApp2 (mkConst ``False.elim [u]) e h
@@ -108,7 +108,7 @@ def mkEqSymm (h : Expr) : MetaM Expr := do
      return mkApp4 (mkConst ``Eq.symm [u]) α a b h
    | none => throwAppBuilderException ``Eq.symm ("equality proof expected" ++ hasTypeMsg h hType)

-/-- Given `h₁ : a = b` and `h₂ : b = c`, returns a proof of `a = c`. -/
+/-- Given `h₁ : a = b` and `h₂ : b = c` returns a proof of `a = c`. -/
 def mkEqTrans (h₁ h₂ : Expr) : MetaM Expr := do
  if h₁.isAppOf ``Eq.refl then
    return h₂
@@ -185,7 +185,7 @@ def mkHEqOfEq (h : Expr) : MetaM Expr := do
  return mkApp4 (mkConst ``heq_of_eq [u]) α a b h

 /--
-If `e` is `@Eq.refl α a`, returns `a`.
+If `e` is `@Eq.refl α a`, return `a`.
 -/
 def isRefl? (e : Expr) : Option Expr := do
  if e.isAppOfArity ``Eq.refl 2 then
@@ -194,7 +194,7 @@ def isRefl? (e : Expr) : Option Expr := do
    none

 /--
-If `e` is `@congrArg α β a b f h`, returns `α`, `f` and `h`.
+If `e` is `@congrArg α β a b f h`, return `α`, `f` and `h`.
 Also works if `e` can be turned into such an application (e.g. `congrFun`).
 -/
 def congrArg? (e : Expr) : MetaM (Option (Expr × Expr × Expr)) := do
@@ -336,14 +336,13 @@ private def withAppBuilderTrace [ToMessageData α] [ToMessageData β]
      throw ex

 /--
-  Returns the application `constName xs`.
+  Return the application `constName xs`.
  It tries to fill the implicit arguments before the last element in `xs`.

  Remark:
  ``mkAppM `arbitrary #[α]`` returns `@arbitrary.{u} α` without synthesizing
  the implicit argument occurring after `α`.
-  Given a `x : ([Decidable p] → Bool) × Nat`, ``mkAppM `Prod.fst #[x]``,
-  returns `@Prod.fst ([Decidable p] → Bool) Nat x`.
+  Given a `x : ([Decidable p] → Bool) × Nat`, ``mkAppM `Prod.fst #[x]`` returns `@Prod.fst ([Decidable p] → Bool) Nat x`.
 -/
 def mkAppM (constName : Name) (xs : Array Expr) : MetaM Expr := do
  withAppBuilderTrace constName xs do withNewMCtxDepth do
@@ -466,9 +465,8 @@ def mkPure (monad : Expr) (e : Expr) : MetaM Expr :=
  mkAppOptM ``Pure.pure #[monad, none, none, e]

 /--
-`mkProjection s fieldName` returns an expression for accessing field `fieldName` of the structure `s`.
-Remark: `fieldName` may be a subfield of `s`.
-/
+  `mkProjection s fieldName` returns an expression for accessing field `fieldName` of the structure `s`.
+  Remark: `fieldName` may be a subfield of `s`. -/
 partial def mkProjection (s : Expr) (fieldName : Name) : MetaM Expr := do
  let type ← inferType s
  let type ← whnf type
@@ -522,11 +520,11 @@ def mkSome (type value : Expr) : MetaM Expr := do
  let u ← getDecLevel type
  return mkApp2 (mkConst ``Option.some [u]) type value

-/-- Returns `Decidable.decide p` -/
+/-- Return `Decidable.decide p` -/
 def mkDecide (p : Expr) : MetaM Expr :=
  mkAppOptM ``Decidable.decide #[p, none]

-/-- Returns a proof for `p : Prop` using `decide p` -/
+/-- Return a proof for `p : Prop` using `decide p` -/
 def mkDecideProof (p : Expr) : MetaM Expr := do
  let decP      ← mkDecide p
  let decEqTrue ← mkEq decP (mkConst ``Bool.true)
@@ -534,75 +532,59 @@ def mkDecideProof (p : Expr) : MetaM Expr := do
  let h         ← mkExpectedTypeHint h decEqTrue
  mkAppM ``of_decide_eq_true #[h]

-/-- Returns `a < b` -/
+/-- Return `a < b` -/
 def mkLt (a b : Expr) : MetaM Expr :=
  mkAppM ``LT.lt #[a, b]

-/-- Returns `a <= b` -/
+/-- Return `a <= b` -/
 def mkLe (a b : Expr) : MetaM Expr :=
  mkAppM ``LE.le #[a, b]

-/-- Returns `Inhabited.default α` -/
+/-- Return `Inhabited.default α` -/
 def mkDefault (α : Expr) : MetaM Expr :=
  mkAppOptM ``Inhabited.default #[α, none]

-/-- Returns `@Classical.ofNonempty α _` -/
+/-- Return `@Classical.ofNonempty α _` -/
 def mkOfNonempty (α : Expr) : MetaM Expr := do
  mkAppOptM ``Classical.ofNonempty #[α, none]

-/-- Returns `funext h` -/
+/-- Return `funext h` -/
 def mkFunExt (h : Expr) : MetaM Expr :=
  mkAppM ``funext #[h]

-/-- Returns `propext h` -/
+/-- Return `propext h` -/
 def mkPropExt (h : Expr) : MetaM Expr :=
  mkAppM ``propext #[h]

-/-- Returns `let_congr h₁ h₂` -/
+/-- Return `let_congr h₁ h₂` -/
 def mkLetCongr (h₁ h₂ : Expr) : MetaM Expr :=
  mkAppM ``let_congr #[h₁, h₂]

-/-- Returns `let_val_congr b h` -/
+/-- Return `let_val_congr b h` -/
 def mkLetValCongr (b h : Expr) : MetaM Expr :=
  mkAppM ``let_val_congr #[b, h]

-/-- Returns `let_body_congr a h` -/
+/-- Return `let_body_congr a h` -/
 def mkLetBodyCongr (a h : Expr) : MetaM Expr :=
  mkAppM ``let_body_congr #[a, h]

-/-- Returns `@of_eq_true p h` -/
-def mkOfEqTrueCore (p : Expr) (h : Expr) : Expr :=
-  match_expr h with
-  | eq_true _ h => h
-  | _ => mkApp2 (mkConst ``of_eq_true) p h
+/-- Return `of_eq_true h` -/
+def mkOfEqTrue (h : Expr) : MetaM Expr :=
+  mkAppM ``of_eq_true #[h]

-/-- Returns `of_eq_true h` -/
-def mkOfEqTrue (h : Expr) : MetaM Expr := do
-  match_expr h with
-  | eq_true _ h => return h
-  | _ => mkAppM ``of_eq_true #[h]
-
-/-- Returns `eq_true h` -/
-def mkEqTrueCore (p : Expr) (h : Expr) : Expr :=
-  match_expr h with
-  | of_eq_true _ h => h
-  | _ => mkApp2 (mkConst ``eq_true) p h
-
-/-- Returns `eq_true h` -/
-def mkEqTrue (h : Expr) : MetaM Expr := do
-  match_expr h with
-  | of_eq_true _ h => return h
-  | _ => return mkApp2 (mkConst ``eq_true) (← inferType h) h
+/-- Return `eq_true h` -/
+def mkEqTrue (h : Expr) : MetaM Expr :=
+  mkAppM ``eq_true #[h]

 /--
-  Returns `eq_false h`
+  Return `eq_false h`
  `h` must have type definitionally equal to `¬ p` in the current
  reducibility setting. -/
 def mkEqFalse (h : Expr) : MetaM Expr :=
  mkAppM ``eq_false #[h]

 /--
-  Returns `eq_false' h`
+  Return `eq_false' h`
  `h` must have type definitionally equal to `p → False` in the current
  reducibility setting. -/
 def mkEqFalse' (h : Expr) : MetaM Expr :=
@@ -620,7 +602,7 @@ def mkImpDepCongrCtx (h₁ h₂ : Expr) : MetaM Expr :=
 def mkForallCongr (h : Expr) : MetaM Expr :=
  mkAppM ``forall_congr #[h]

-/-- Returns instance for `[Monad m]` if there is one -/
+/-- Return instance for `[Monad m]` if there is one -/
 def isMonad? (m : Expr) : MetaM (Option Expr) :=
  try
    let monadType ← mkAppM `Monad #[m]
@@ -631,52 +613,52 @@ def isMonad? (m : Expr) : MetaM (Option Expr) :=
  catch _ =>
    pure none

-/-- Returns `(n : type)`, a numeric literal of type `type`. The method fails if we don't have an instance `OfNat type n` -/
+/-- Return `(n : type)`, a numeric literal of type `type`. The method fails if we don't have an instance `OfNat type n` -/
 def mkNumeral (type : Expr) (n : Nat) : MetaM Expr := do
  let u ← getDecLevel type
  let inst ← synthInstance (mkApp2 (mkConst ``OfNat [u]) type (mkRawNatLit n))
  return mkApp3 (mkConst ``OfNat.ofNat [u]) type (mkRawNatLit n) inst

 /--
-Returns `a op b`, where `op` has name `opName` and is implemented using the typeclass `className`.
-This method assumes `a` and `b` have the same type, and typeclass `className` is heterogeneous.
-Examples of supported classes: `HAdd`, `HSub`, `HMul`.
-We use heterogeneous operators to ensure we have a uniform representation.
-/
+  Return `a op b`, where `op` has name `opName` and is implemented using the typeclass `className`.
+  This method assumes `a` and `b` have the same type, and typeclass `className` is heterogeneous.
+  Examples of supported classes: `HAdd`, `HSub`, `HMul`.
+  We use heterogeneous operators to ensure we have a uniform representation.
+  -/
 private def mkBinaryOp (className : Name) (opName : Name) (a b : Expr) : MetaM Expr := do
  let aType ← inferType a
  let u ← getDecLevel aType
  let inst ← synthInstance (mkApp3 (mkConst className [u, u, u]) aType aType aType)
  return mkApp6 (mkConst opName [u, u, u]) aType aType aType inst a b

-/-- Returns `a + b` using a heterogeneous `+`. This method assumes `a` and `b` have the same type. -/
+/-- Return `a + b` using a heterogeneous `+`. This method assumes `a` and `b` have the same type. -/
 def mkAdd (a b : Expr) : MetaM Expr := mkBinaryOp ``HAdd ``HAdd.hAdd a b

-/-- Returns `a - b` using a heterogeneous `-`. This method assumes `a` and `b` have the same type. -/
+/-- Return `a - b` using a heterogeneous `-`. This method assumes `a` and `b` have the same type. -/
 def mkSub (a b : Expr) : MetaM Expr := mkBinaryOp ``HSub ``HSub.hSub a b

-/-- Returns `a * b` using a heterogeneous `*`. This method assumes `a` and `b` have the same type. -/
+/-- Return `a * b` using a heterogeneous `*`. This method assumes `a` and `b` have the same type. -/
 def mkMul (a b : Expr) : MetaM Expr := mkBinaryOp ``HMul ``HMul.hMul a b

 /--
-Returns `a r b`, where `r` has name `rName` and is implemented using the typeclass `className`.
-This method assumes `a` and `b` have the same type.
-Examples of supported classes: `LE` and `LT`.
-We use heterogeneous operators to ensure we have a uniform representation.
-/
+  Return `a r b`, where `r` has name `rName` and is implemented using the typeclass `className`.
+  This method assumes `a` and `b` have the same type.
+  Examples of supported classes: `LE` and `LT`.
+  We use heterogeneous operators to ensure we have a uniform representation.
+  -/
 private def mkBinaryRel (className : Name) (rName : Name) (a b : Expr) : MetaM Expr := do
  let aType ← inferType a
  let u ← getDecLevel aType
  let inst ← synthInstance (mkApp (mkConst className [u]) aType)
  return mkApp4 (mkConst rName [u]) aType inst a b

-/-- Returns `a ≤ b`. This method assumes `a` and `b` have the same type. -/
+/-- Return `a ≤ b`. This method assumes `a` and `b` have the same type. -/
 def mkLE (a b : Expr) : MetaM Expr := mkBinaryRel ``LE ``LE.le a b

-/-- Returns `a < b`. This method assumes `a` and `b` have the same type. -/
+/-- Return `a < b`. This method assumes `a` and `b` have the same type. -/
 def mkLT (a b : Expr) : MetaM Expr := mkBinaryRel ``LT ``LT.lt a b

-/-- Given `h : a = b`, returns a proof for `a ↔ b`. -/
+/-- Given `h : a = b`, return a proof for `a ↔ b`. -/
 def mkIffOfEq (h : Expr) : MetaM Expr := do
  if h.isAppOfArity ``propext 3 then
    return h.appArg!
--- a/src/Lean/Meta/Basic.lean
+++ b/src/Lean/Meta/Basic.lean
@@ -1964,22 +1964,15 @@ def sortFVarIds (fvarIds : Array FVarId) : MetaM (Array FVarId) := do

 end Methods

-/--
-Return `some info` if `declName` is an inductive predicate where `info : InductiveVal`.
-That is, `inductive` type in `Prop`.
-/
-def isInductivePredicate? (declName : Name) : MetaM (Option InductiveVal) := do
-  match (← getEnv).find? declName with
-  | some (.inductInfo info) =>
-    forallTelescopeReducing info.type fun _ type => do
-      match (← whnfD type) with
-      | .sort u .. => if u == levelZero then return some info else return none
-      | _ => return none
-  | _ => return none
-
 /-- Return `true` if `declName` is an inductive predicate. That is, `inductive` type in `Prop`. -/
 def isInductivePredicate (declName : Name) : MetaM Bool := do
-  return (← isInductivePredicate? declName).isSome
+  match (← getEnv).find? declName with
+  | some (.inductInfo { type := type, ..}) =>
+    forallTelescopeReducing type fun _ type => do
+      match (← whnfD type) with
+      | .sort u .. => return u == levelZero
+      | _ => return false
+  | _ => return false

 def isListLevelDefEqAux : List Level → List Level → MetaM Bool
  | [],    []    => return true
--- a/src/Lean/Meta/Tactic/FVarSubst.lean
+++ b/src/Lean/Meta/Tactic/FVarSubst.lean
@@ -35,7 +35,7 @@ def insert (s : FVarSubst) (fvarId : FVarId) (v : Expr) : FVarSubst :=
  if s.contains fvarId then s
  else
    let map := s.map.mapVal fun e => e.replaceFVarId fvarId v;
-    { map := map.insertNew fvarId v }
+    { map := map.insert fvarId v }

 def erase (s : FVarSubst) (fvarId : FVarId) : FVarSubst :=
  { map := s.map.erase fvarId }
--- a/src/Lean/Meta/Tactic/Grind.lean
+++ b/src/Lean/Meta/Tactic/Grind.lean
@@ -24,7 +24,6 @@ import Lean.Meta.Tactic.Grind.EMatchTheorem
 import Lean.Meta.Tactic.Grind.EMatch
 import Lean.Meta.Tactic.Grind.Main
 import Lean.Meta.Tactic.Grind.CasesMatch
-import Lean.Meta.Tactic.Grind.Arith

 namespace Lean

@@ -43,14 +42,6 @@ builtin_initialize registerTraceClass `grind.simp
 builtin_initialize registerTraceClass `grind.split
 builtin_initialize registerTraceClass `grind.split.candidate
 builtin_initialize registerTraceClass `grind.split.resolved
-builtin_initialize registerTraceClass `grind.offset
-builtin_initialize registerTraceClass `grind.offset.dist
-builtin_initialize registerTraceClass `grind.offset.internalize
-builtin_initialize registerTraceClass `grind.offset.internalize.term (inherited := true)
-builtin_initialize registerTraceClass `grind.offset.propagate
-builtin_initialize registerTraceClass `grind.offset.eq
-builtin_initialize registerTraceClass `grind.offset.eq.to (inherited := true)
-builtin_initialize registerTraceClass `grind.offset.eq.from (inherited := true)

 /-! Trace options for `grind` developers -/
 builtin_initialize registerTraceClass `grind.debug
@@ -62,7 +53,5 @@ builtin_initialize registerTraceClass `grind.debug.parent
 builtin_initialize registerTraceClass `grind.debug.final
 builtin_initialize registerTraceClass `grind.debug.forallPropagator
 builtin_initialize registerTraceClass `grind.debug.split
-builtin_initialize registerTraceClass `grind.debug.canon
-builtin_initialize registerTraceClass `grind.debug.offset
-builtin_initialize registerTraceClass `grind.debug.offset.proof
+
 end Lean
--- a/src/Lean/Meta/Tactic/Grind/Arith.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith.lean
@@ -1,10 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Lean.Meta.Tactic.Grind.Arith.Util
-import Lean.Meta.Tactic.Grind.Arith.Types
-import Lean.Meta.Tactic.Grind.Arith.Offset
-import Lean.Meta.Tactic.Grind.Arith.Main
--- a/src/Lean/Meta/Tactic/Grind/Arith/Internalize.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith/Internalize.lean
@@ -1,14 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Lean.Meta.Tactic.Grind.Arith.Offset
-
-namespace Lean.Meta.Grind.Arith
-
-def internalize (e : Expr) (parent? : Option Expr) : GoalM Unit := do
-  Offset.internalize e parent?
-
-end Lean.Meta.Grind.Arith
--- a/src/Lean/Meta/Tactic/Grind/Arith/Inv.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith/Inv.lean
@@ -1,14 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Lean.Meta.Tactic.Grind.Arith.Offset
-
-namespace Lean.Meta.Grind.Arith
-
-def checkInvariants : GoalM Unit :=
-  Offset.checkInvariants
-
-end Lean.Meta.Grind.Arith
--- a/src/Lean/Meta/Tactic/Grind/Arith/Main.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith/Main.lean
@@ -1,34 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Lean.Meta.Tactic.Grind.PropagatorAttr
-import Lean.Meta.Tactic.Grind.Arith.Offset
-
-namespace Lean.Meta.Grind.Arith
-
-namespace Offset
-def isCnstr? (e : Expr) : GoalM (Option (Cnstr NodeId)) :=
-  return (← get).arith.offset.cnstrs.find? { expr := e }
-
-def assertTrue (c : Cnstr NodeId) (p : Expr) : GoalM Unit := do
-  addEdge c.u c.v c.k (← mkOfEqTrue p)
-
-def assertFalse (c : Cnstr NodeId) (p : Expr) : GoalM Unit := do
-  let p := mkOfNegEqFalse (← get').nodes c p
-  let c := c.neg
-  addEdge c.u c.v c.k p
-
-end Offset
-
-builtin_grind_propagator propagateLE ↓LE.le := fun e => do
-  if (← isEqTrue e) then
-    if let some c ← Offset.isCnstr? e then
-      Offset.assertTrue c (← mkEqTrueProof e)
-  if (← isEqFalse e) then
-    if let some c ← Offset.isCnstr? e then
-      Offset.assertFalse c (← mkEqFalseProof e)
-
-end Lean.Meta.Grind.Arith
--- a/src/Lean/Meta/Tactic/Grind/Arith/Model.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith/Model.lean
@@ -1,46 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Lean.Meta.Basic
-import Lean.Meta.Tactic.Grind.Types
-import Lean.Meta.Tactic.Grind.Util
-
-namespace Lean.Meta.Grind.Arith.Offset
-/-- Construct a model that statisfies all offset constraints -/
-def mkModel (goal : Goal) : MetaM (Array (Expr × Nat)) := do
-  let s := goal.arith.offset
-  let nodes := s.nodes
-  let mut pre : Array (Option Int) := mkArray nodes.size none
-  for u in [:nodes.size] do
-    let val? := s.sources[u]!.foldl (init := @none Int) fun val? v k => Id.run do
-      let some va := pre[v]! | return val?
-      let val' := va - k
-      let some val := val? | return val'
-      if val' > val then return val' else val?
-    let val? := s.targets[u]!.foldl (init := val?) fun val? v k => Id.run do
-      let some va := pre[v]! | return val?
-      let val' := va + k
-      let some val := val? | return val'
-      if val' < val then return val' else val?
-    let val := val?.getD 0
-    pre := pre.set! u (some val)
-  let min := pre.foldl (init := 0) fun min val? => Id.run do
-    let some val := val? | return min
-    if val < min then val else min
-  let mut r := {}
-  for u in [:nodes.size] do
-    let some val := pre[u]! | unreachable!
-    let val := (val - min).toNat
-    let e := nodes[u]!
-    /-
-    We should not include the assignment for auxiliary offset terms since
-    they do not provide any additional information.
-    -/
-    if (isNatOffset? e).isNone && isNatNum? e != some 0 then
-      r := r.push (e, val)
-  return r
-
-end Lean.Meta.Grind.Arith.Offset
--- a/src/Lean/Meta/Tactic/Grind/Arith/Offset.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith/Offset.lean
@@ -1,335 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Init.Grind.Offset
-import Lean.Meta.Tactic.Grind.Types
-import Lean.Meta.Tactic.Grind.Arith.ProofUtil
-
-namespace Lean.Meta.Grind.Arith.Offset
-/-!
-This module implements a decision procedure for offset constraints of the form:
-```
-x + k ≤ y
-x ≤ y + k
-```
-where `k` is a numeral.
-Each constraint is represented as an edge in a weighted graph.
-The constraint `x + k ≤ y` is represented as a negative edge.
-The shortest path between two nodes in the graph corresponds to an implied inequality.
-When adding a new edge, the state is considered unsatisfiable if the new edge creates a negative cycle.
-An incremental Floyd-Warshall algorithm is used to find the shortest paths between all nodes.
-This module can also handle offset equalities of the form `x + k = y` by representing them with two edges:
-```
-x + k ≤ y
-y ≤ x + k
-```
-The main advantage of this module over a full linear integer arithmetic procedure is
-its ability to efficiently detect all implied equalities and inequalities.
-/
-
-def get' : GoalM State := do
-  return (← get).arith.offset
-
-@[inline] def modify' (f : State → State) : GoalM Unit := do
-  modify fun s => { s with arith.offset := f s.arith.offset }
-
-def mkNode (expr : Expr) : GoalM NodeId := do
-  if let some nodeId := (← get').nodeMap.find? { expr } then
-    return nodeId
-  let nodeId : NodeId := (← get').nodes.size
-  trace[grind.offset.internalize.term] "{expr} ↦ #{nodeId}"
-  modify' fun s => { s with
-    nodes   := s.nodes.push expr
-    nodeMap := s.nodeMap.insert { expr } nodeId
-    sources := s.sources.push {}
-    targets := s.targets.push {}
-    proofs  := s.proofs.push {}
-  }
-  markAsOffsetTerm expr
-  return nodeId
-
-private def getExpr (u : NodeId) : GoalM Expr := do
-  return (← get').nodes[u]!
-
-private def getDist? (u v : NodeId) : GoalM (Option Int) := do
-  return (← get').targets[u]!.find? v
-
-private def getProof? (u v : NodeId) : GoalM (Option ProofInfo) := do
-  return (← get').proofs[u]!.find? v
-
-private def getNodeId (e : Expr) : GoalM NodeId := do
-  let some nodeId := (← get').nodeMap.find? { expr := e }
-    | throwError "internal `grind` error, term has not been internalized by offset module{indentExpr e}"
-  return nodeId
-
-/--
-Returns a proof for `u + k ≤ v` (or `u ≤ v + k`) where `k` is the
-shortest path between `u` and `v`.
-/
-private partial def mkProofForPath (u v : NodeId) : GoalM Expr := do
-  go (← getProof? u v).get!
-where
-  go (p : ProofInfo) : GoalM Expr := do
-    if u == p.w then
-      return p.proof
-    else
-      let p' := (← getProof? u p.w).get!
-      go (mkTrans (← get').nodes p' p v)
-
-/--
-Given a new edge edge `u --(kuv)--> v` justified by proof `huv` s.t.
-it creates a negative cycle with the existing path `v --{kvu}-->* u`, i.e., `kuv + kvu < 0`,
-this function closes the current goal by constructing a proof of `False`.
-/
-private def setUnsat (u v : NodeId) (kuv : Int) (huv : Expr) (kvu : Int) : GoalM Unit := do
-  assert! kuv + kvu < 0
-  let hvu ← mkProofForPath v u
-  let u ← getExpr u
-  let v ← getExpr v
-  closeGoal (mkUnsatProof u v kuv huv kvu hvu)
-
-/-- Sets the new shortest distance `k` between nodes `u` and `v`. -/
-private def setDist (u v : NodeId) (k : Int) : GoalM Unit := do
-  trace[grind.offset.dist] "{({ u, v, k : Cnstr NodeId})}"
-  modify' fun s => { s with
-    targets := s.targets.modify u fun es => es.insert v k
-    sources := s.sources.modify v fun es => es.insert u k
-  }
-
-private def setProof (u v : NodeId) (p : ProofInfo) : GoalM Unit := do
-  modify' fun s => { s with
-    proofs := s.proofs.modify u fun es => es.insert v p
-  }
-
-@[inline]
-private def forEachSourceOf (u : NodeId) (f : NodeId → Int → GoalM Unit) : GoalM Unit := do
-  (← get').sources[u]!.forM f
-
-@[inline]
-private def forEachTargetOf (u : NodeId) (f : NodeId → Int → GoalM Unit) : GoalM Unit := do
-  (← get').targets[u]!.forM f
-
-/-- Returns `true` if `k` is smaller than the shortest distance between `u` and `v` -/
-private def isShorter (u v : NodeId) (k : Int) : GoalM Bool := do
-  if let some k' ← getDist? u v then
-    return k < k'
-  else
-    return true
-
-/--
-Tries to assign `e` to `True`, which is represented by constraint `c` (from `u` to `v`), using the
-path `u --(k)--> v`.
-/
-private def propagateTrue (u v : NodeId) (k : Int) (c : Cnstr NodeId) (e : Expr) : GoalM Bool := do
-  if k ≤ c.k then
-    trace[grind.offset.propagate] "{{ u, v, k : Cnstr NodeId}} ==> {e} = True"
-    let kuv ← mkProofForPath u v
-    let u ← getExpr u
-    let v ← getExpr v
-    pushEqTrue e <| mkPropagateEqTrueProof u v k kuv c.k
-    return true
-  return false
-
-/--
-Tries to assign `e` to `False`, which is represented by constraint `c` (from `v` to `u`), using the
-path `u --(k)--> v`.
-/
-private def propagateFalse (u v : NodeId) (k : Int) (c : Cnstr NodeId) (e : Expr) : GoalM Bool := do
-  if k + c.k < 0 then
-    trace[grind.offset.propagate] "{{ u, v, k : Cnstr NodeId}} ==> {e} = False"
-    let kuv ← mkProofForPath u v
-    let u ← getExpr u
-    let v ← getExpr v
-    pushEqFalse e <| mkPropagateEqFalseProof u v k kuv c.k
-  return false
-
-/--
-Auxiliary function for implementing `propagateAll`.
-Traverses the constraints `c` (representing an expression `e`) s.t.
-`c.u = u` and `c.v = v`, it removes `c` from the list of constraints
-associated with `(u, v)` IF
- `e` is already assigned, or
- `f c e` returns true
-/
-@[inline]
-private def updateCnstrsOf (u v : NodeId) (f : Cnstr NodeId → Expr → GoalM Bool) : GoalM Unit := do
-  if let some cs := (← get').cnstrsOf.find? (u, v) then
-    let cs' ← cs.filterM fun (c, e) => do
-      if (← isEqTrue e <||> isEqFalse e) then
-        return false -- constraint was already assigned
-      else
-        return !(← f c e)
-    modify' fun s => { s with cnstrsOf := s.cnstrsOf.insert (u, v) cs' }
-
-/-- Equality propagation. -/
-private def propagateEq (u v : NodeId) (k : Int) : GoalM Unit := do
-  if k != 0 then return ()
-  let some k' ← getDist? v u | return ()
-  if k' != 0 then return ()
-  let ue ← getExpr u
-  let ve ← getExpr v
-  if (← isEqv ue ve) then return ()
-  let huv ← mkProofForPath u v
-  let hvu ← mkProofForPath v u
-  trace[grind.offset.eq.from] "{ue}, {ve}"
-  pushEq ue ve <| mkApp4 (mkConst ``Grind.Nat.eq_of_le_of_le) ue ve huv hvu
-
-/-- Performs constraint propagation. -/
-private def propagateAll (u v : NodeId) (k : Int) : GoalM Unit := do
-  updateCnstrsOf u v fun c e => return !(← propagateTrue u v k c e)
-  updateCnstrsOf v u fun c e => return !(← propagateFalse u v k c e)
-  propagateEq u v k
-
-/--
-If `isShorter u v k`, updates the shortest distance between `u` and `v`.
-`w` is the penultimate node in the path from `u` to `v`.
-/
-private def updateIfShorter (u v : NodeId) (k : Int) (w : NodeId) : GoalM Unit := do
-  if (← isShorter u v k) then
-    setDist u v k
-    setProof u v (← getProof? w v).get!
-    propagateAll u v k
-
-/--
-Adds an edge `u --(k) --> v` justified by the proof term `p`, and then
-if no negative cycle was created, updates the shortest distance of affected
-node pairs.
-/
-def addEdge (u : NodeId) (v : NodeId) (k : Int) (p : Expr) : GoalM Unit := do
-  if (← isInconsistent) then return ()
-  if let some k' ← getDist? v u then
-    if k'+k < 0 then
-      setUnsat u v k p k'
-      return ()
-  if (← isShorter u v k) then
-    setDist u v k
-    setProof u v { w := u, k, proof := p }
-    propagateAll u v k
-    update
-where
-  update : GoalM Unit := do
-    forEachTargetOf v fun j k₂ => do
-      /- Check whether new path: `u -(k)-> v -(k₂)-> j` is shorter -/
-      updateIfShorter u j (k+k₂) v
-    forEachSourceOf u fun i k₁ => do
-      /- Check whether new path: `i -(k₁)-> u -(k)-> v` is shorter -/
-      updateIfShorter i v (k₁+k) u
-      forEachTargetOf v fun j k₂ => do
-        /- Check whether new path: `i -(k₁)-> u -(k)-> v -(k₂) -> j` is shorter -/
-        updateIfShorter i j (k₁+k+k₂) v
-
-private def internalizeCnstr (e : Expr) (c : Cnstr Expr) : GoalM Unit := do
-  let u ← mkNode c.u
-  let v ← mkNode c.v
-  let c := { c with u, v }
-  if let some k ← getDist? u v then
-    if (← propagateTrue u v k c e) then
-      return ()
-  if let some k ← getDist? v u then
-    if (← propagateFalse v u k c e) then
-      return ()
-  trace[grind.offset.internalize] "{e} ↦ {c}"
-  modify' fun s => { s with
-    cnstrs   := s.cnstrs.insert { expr := e } c
-    cnstrsOf :=
-      let cs := if let some cs := s.cnstrsOf.find? (u, v) then (c, e) :: cs else [(c, e)]
-      s.cnstrsOf.insert (u, v) cs
-  }
-
-private def getZeroNode : GoalM NodeId := do
-  mkNode (← getNatZeroExpr)
-
-/-- Internalize `e` of the form `b + k` -/
-private def internalizeTerm (e : Expr) (b : Expr) (k : Nat) : GoalM Unit := do
-  -- `e` is of the form `b + k`
-  let u ← mkNode e
-  let v ← mkNode b
-  -- `u = v + k`. So, we add edges for `u ≤ v + k` and `v + k ≤ u`.
-  let h := mkApp (mkConst ``Nat.le_refl) e
-  addEdge u v k h
-  addEdge v u (-k) h
-  -- `0 + k ≤ u`
-  let z ← getZeroNode
-  addEdge z u (-k) <| mkApp2 (mkConst ``Grind.Nat.le_offset) b (toExpr k)
-
-/--
-Returns `true`, if `parent?` is relevant for internalization.
-For example, we do not want to internalize an offset term that
-is the child of an addition. This kind of term will be processed by the
-more general linear arithmetic module.
-/
-private def isRelevantParent (parent? : Option Expr) : GoalM Bool := do
-  let some parent := parent? | return false
-  let z ← getNatZeroExpr
-  return !isNatAdd parent && (isNatOffsetCnstr? parent z).isNone
-
-private def isEqParent (parent? : Option Expr) : Bool := Id.run do
-  let some parent := parent? | return false
-  return parent.isEq
-
-def internalize (e : Expr) (parent? : Option Expr) : GoalM Unit := do
-  let z ← getNatZeroExpr
-  if let some c := isNatOffsetCnstr? e z then
-    internalizeCnstr e c
-  else if (← isRelevantParent parent?) then
-    if let some (b, k) := isNatOffset? e then
-      internalizeTerm e b k
-    else if let some k := isNatNum? e then
-      -- core module has support for detecting equality between literals
-      unless isEqParent parent? do
-        internalizeTerm e z k
-
-@[export lean_process_new_offset_eq]
-def processNewOffsetEqImpl (a b : Expr) : GoalM Unit := do
-  unless isSameExpr a b do
-    trace[grind.offset.eq.to] "{a}, {b}"
-    let u ← getNodeId a
-    let v ← getNodeId b
-    let h ← mkEqProof a b
-    addEdge u v 0 <| mkApp3 (mkConst ``Grind.Nat.le_of_eq_1) a b h
-    addEdge v u 0 <| mkApp3 (mkConst ``Grind.Nat.le_of_eq_2) a b h
-
-@[export lean_process_new_offset_eq_lit]
-def processNewOffsetEqLitImpl (a b : Expr) : GoalM Unit := do
-  unless isSameExpr a b do
-    trace[grind.offset.eq.to] "{a}, {b}"
-    let some k := isNatNum? b | unreachable!
-    let u ← getNodeId a
-    let z ← mkNode (← getNatZeroExpr)
-    let h ← mkEqProof a b
-    addEdge u z k <| mkApp3 (mkConst ``Grind.Nat.le_of_eq_1) a b h
-    addEdge z u (-k) <| mkApp3 (mkConst ``Grind.Nat.le_of_eq_2) a b h
-
-def traceDists : GoalM Unit := do
-  let s ← get'
-  for u in [:s.targets.size], es in s.targets.toArray do
-    for (v, k) in es do
-      trace[grind.offset.dist] "#{u} -({k})-> #{v}"
-
-def Cnstr.toExpr (c : Cnstr NodeId) : GoalM Expr := do
-  let u := (← get').nodes[c.u]!
-  let v := (← get').nodes[c.v]!
-  if c.k == 0 then
-    return mkNatLE u v
-  else if c.k < 0 then
-    return mkNatLE (mkNatAdd u (Lean.toExpr ((-c.k).toNat))) v
-  else
-    return mkNatLE u (mkNatAdd v (Lean.toExpr c.k.toNat))
-
-def checkInvariants : GoalM Unit := do
-  let s ← get'
-  for u in [:s.targets.size], es in s.targets.toArray do
-    for (v, k) in es do
-      let c : Cnstr NodeId := { u, v, k }
-      trace[grind.debug.offset] "{c}"
-      let p ← mkProofForPath u v
-      trace[grind.debug.offset.proof] "{p} : {← inferType p}"
-      check p
-      unless (← withDefault <| isDefEq (← inferType p) (← Cnstr.toExpr c)) do
-        trace[grind.debug.offset.proof] "failed: {← inferType p} =?= {← Cnstr.toExpr c}"
-        unreachable!
-
-end Lean.Meta.Grind.Arith.Offset
--- a/src/Lean/Meta/Tactic/Grind/Arith/ProofUtil.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith/ProofUtil.lean
@@ -1,168 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Init.Grind.Offset
-import Init.Grind.Lemmas
-import Lean.Meta.Tactic.Grind.Types
-
-namespace Lean.Meta.Grind.Arith
-
-/-!
-Helper functions for constructing proof terms in the arithmetic procedures.
-/
-
-namespace Offset
-
-/-- Returns a proof for `true = true` -/
-def rfl_true : Expr := mkConst ``Grind.rfl_true
-
-private def toExprN (n : Int) :=
-  assert! n >= 0
-  toExpr n.toNat
-
-open Lean.Grind in
-/--
-Assume `pi₁` is `{ w := u, k := k₁, proof := p₁ }` and `pi₂` is `{ w := w, k := k₂, proof := p₂ }`
-`p₁` is the proof for edge `u -(k₁) → w` and `p₂` the proof for edge `w -(k₂)-> v`.
-Then, this function returns a proof for edge `u -(k₁+k₂) -> v`.
-/
-def mkTrans (nodes : PArray Expr) (pi₁ : ProofInfo) (pi₂ : ProofInfo) (v : NodeId) : ProofInfo :=
-  let { w := u, k := k₁, proof := p₁ } := pi₁
-  let { w, k := k₂, proof := p₂ } := pi₂
-  let u := nodes[u]!
-  let w := nodes[w]!
-  let v := nodes[v]!
-  let p := if k₁ == 0 then
-    if k₂ == 0 then
-      -- u ≤ w, w ≤ v
-      mkApp5 (mkConst ``Nat.le_trans) u w v p₁ p₂
-    else if k₂ > 0 then
-      -- u ≤ v, w ≤ v + k₂
-      mkApp6 (mkConst ``Nat.le_ro) u w v (toExprN k₂) p₁ p₂
-    else
-      let k₂ := - k₂
-      -- u ≤ w, w + k₂ ≤ v
-      mkApp6 (mkConst ``Nat.le_lo) u w v (toExprN k₂) p₁ p₂
-  else if k₁ < 0 then
-    let k₁ := -k₁
-    if k₂ == 0 then
-      mkApp6 (mkConst ``Nat.lo_le) u w v (toExprN k₁) p₁ p₂
-    else if k₂ < 0 then
-      let k₂ := -k₂
-      mkApp7 (mkConst ``Nat.lo_lo) u w v (toExprN k₁) (toExprN k₂) p₁ p₂
-    else
-      let ke₁ := toExprN k₁
-      let ke₂ := toExprN k₂
-      if k₁ > k₂ then
-        mkApp8 (mkConst ``Nat.lo_ro_1) u w v ke₁ ke₂ rfl_true p₁ p₂
-      else
-        mkApp7 (mkConst ``Nat.lo_ro_2) u w v ke₁ ke₂ p₁ p₂
-  else
-    let ke₁ := toExprN k₁
-    if k₂ == 0 then
-      mkApp6 (mkConst ``Nat.ro_le) u w v ke₁ p₁ p₂
-    else if k₂ < 0 then
-      let k₂  := -k₂
-      let ke₂ := toExprN k₂
-       if k₂ > k₁ then
-         mkApp8 (mkConst ``Nat.ro_lo_2) u w v ke₁ ke₂ rfl_true p₁ p₂
-       else
-         mkApp7 (mkConst ``Nat.ro_lo_1) u w v ke₁ ke₂ p₁ p₂
-    else
-      let ke₂ := toExprN k₂
-      mkApp7 (mkConst ``Nat.ro_ro) u w v ke₁ ke₂ p₁ p₂
-  { w := pi₁.w, k := k₁+k₂, proof := p }
-
-open Lean.Grind in
-def mkOfNegEqFalse (nodes : PArray Expr) (c : Cnstr NodeId) (h : Expr) : Expr :=
-  let u := nodes[c.u]!
-  let v := nodes[c.v]!
-  if c.k == 0 then
-    mkApp3 (mkConst ``Nat.of_le_eq_false) u v h
-  else if c.k == -1 then
-    mkApp3 (mkConst ``Nat.of_lo_eq_false_1) u v h
-  else if c.k < 0 then
-    mkApp4 (mkConst ``Nat.of_lo_eq_false) u v (toExprN (-c.k)) h
-  else
-    mkApp4 (mkConst ``Nat.of_ro_eq_false) u v (toExprN c.k) h
-
-/--
-Returns a proof of `False` using a negative cycle composed of
- `u --(kuv)--> v` with proof `huv`
- `v --(kvu)--> u` with proof `hvu`
-/
-def mkUnsatProof (u v : Expr) (kuv : Int) (huv : Expr) (kvu : Int) (hvu : Expr) : Expr :=
-  if kuv == 0 then
-    assert! kvu < 0
-    mkApp6 (mkConst ``Grind.Nat.unsat_le_lo) u v (toExprN (-kvu)) rfl_true huv hvu
-  else if kvu == 0 then
-    mkApp6 (mkConst ``Grind.Nat.unsat_le_lo) v u (toExprN (-kuv)) rfl_true hvu huv
-  else if kuv < 0 then
-    if kvu > 0 then
-      mkApp7 (mkConst ``Grind.Nat.unsat_lo_ro) u v (toExprN (-kuv)) (toExprN kvu) rfl_true huv hvu
-    else
-      assert! kvu < 0
-      mkApp7 (mkConst ``Grind.Nat.unsat_lo_lo) u v (toExprN (-kuv)) (toExprN (-kvu)) rfl_true huv hvu
-  else
-    assert! kuv > 0 && kvu < 0
-    mkApp7 (mkConst ``Grind.Nat.unsat_lo_ro) v u (toExprN (-kvu)) (toExprN kuv) rfl_true hvu huv
-
-/--
-Given a path `u --(kuv)--> v` justified by proof `huv`,
-construct a proof of `e = True` where `e` is a term corresponding to the edgen `u --(k') --> v`
-s.t. `k ≤ k'`
-/
-def mkPropagateEqTrueProof (u v : Expr) (k : Int) (huv : Expr) (k' : Int) : Expr :=
-  if k == 0 then
-    if k' == 0 then
-      mkApp3 (mkConst ``Grind.Nat.le_eq_true_of_le) u v huv
-    else
-      assert! k' > 0
-      mkApp4 (mkConst ``Grind.Nat.ro_eq_true_of_le) u v (toExprN k') huv
-  else if k < 0 then
-    let k := -k
-    if k' == 0 then
-      mkApp4 (mkConst ``Grind.Nat.le_eq_true_of_lo) u v (toExprN k) huv
-    else if k' < 0 then
-      let k' := -k'
-      mkApp6 (mkConst ``Grind.Nat.lo_eq_true_of_lo) u v (toExprN k) (toExprN k') rfl_true huv
-    else
-      assert! k' > 0
-      mkApp5 (mkConst ``Grind.Nat.ro_eq_true_of_lo) u v (toExprN k) (toExprN k') huv
-  else
-    assert! k > 0
-    assert! k' > 0
-    mkApp6 (mkConst ``Grind.Nat.ro_eq_true_of_ro) u v (toExprN k) (toExprN k') rfl_true huv
-
-/--
-Given a path `u --(kuv)--> v` justified by proof `huv`,
-construct a proof of `e = False` where `e` is a term corresponding to the edgen `v --(k') --> u`
-s.t. `k+k' < 0`
-/
-def mkPropagateEqFalseProof (u v : Expr) (k : Int) (huv : Expr) (k' : Int) : Expr :=
-  if k == 0 then
-    assert! k' < 0
-    let k' := -k'
-    mkApp5 (mkConst ``Grind.Nat.lo_eq_false_of_le) u v (toExprN k') rfl_true huv
-  else if k < 0 then
-    let k := -k
-    if k' == 0 then
-      mkApp5 (mkConst ``Grind.Nat.le_eq_false_of_lo) u v (toExprN k) rfl_true huv
-    else if k' < 0 then
-      let k' := -k'
-      mkApp6 (mkConst ``Grind.Nat.lo_eq_false_of_lo) u v (toExprN k) (toExprN k') rfl_true huv
-    else
-      assert! k' > 0
-      mkApp6 (mkConst ``Grind.Nat.ro_eq_false_of_lo) u v (toExprN k) (toExprN k') rfl_true huv
-  else
-    assert! k > 0
-    assert! k' < 0
-    let k' := -k'
-    mkApp6 (mkConst ``Grind.Nat.lo_eq_false_of_ro) u v (toExprN k) (toExprN k') rfl_true huv
-
-end Offset
-
-end Lean.Meta.Grind.Arith
--- a/src/Lean/Meta/Tactic/Grind/Arith/Types.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith/Types.lean
@@ -1,66 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Lean.Data.PersistentArray
-import Lean.Meta.Tactic.Grind.ENodeKey
-import Lean.Meta.Tactic.Grind.Arith.Util
-
-namespace Lean.Meta.Grind.Arith
-
-namespace Offset
-
-abbrev NodeId := Nat
-
-instance : ToMessageData (Offset.Cnstr NodeId) where
-  toMessageData c := Offset.toMessageData (α := NodeId) (inst := { toMessageData n := m!"#{n}" }) c
-
-/-- Auxiliary structure used for proof extraction.  -/
-structure ProofInfo where
-  w     : NodeId
-  k     : Int
-  proof : Expr
-  deriving Inhabited
-
-/-- State of the constraint offset procedure. -/
-structure State where
-  /-- Mapping from `NodeId` to the `Expr` represented by the node. -/
-  nodes    : PArray Expr := {}
-  /-- Mapping from `Expr` to a node representing it. -/
-  nodeMap  : PHashMap ENodeKey NodeId := {}
-  /-- Mapping from `Expr` representing inequalites to constraints. -/
-  cnstrs   : PHashMap ENodeKey (Cnstr NodeId) := {}
-  /--
-  Mapping from pairs `(u, v)` to a list of offset constraints on `u` and `v`.
-  We use this mapping to implement exhaustive constraint propagation.
-  -/
-  cnstrsOf : PHashMap (NodeId × NodeId) (List (Cnstr NodeId × Expr)) := {}
-  /--
-  For each node with id `u`, `sources[u]` contains
-  pairs `(v, k)` s.t. there is a path from `v` to `u` with weight `k`.
-  -/
-  sources  : PArray (AssocList NodeId Int) := {}
-  /--
-  For each node with id `u`, `targets[u]` contains
-  pairs `(v, k)` s.t. there is a path from `u` to `v` with weight `k`.
-  -/
-  targets  : PArray (AssocList NodeId Int) := {}
-  /--
-  Proof reconstruction information. For each node with id `u`, `proofs[u]` contains
-  pairs `(v, { w, proof })` s.t. there is a path from `u` to `v`, and
-  `w` is the penultimate node in the path, and `proof` is the justification for
-  the last edge.
-  -/
-  proofs   : PArray (AssocList NodeId ProofInfo) := {}
-  deriving Inhabited
-
-end Offset
-
-/-- State for the arithmetic procedures. -/
-structure State where
-  offset : Offset.State := {}
-  deriving Inhabited
-
-end Lean.Meta.Grind.Arith
--- a/src/Lean/Meta/Tactic/Grind/Arith/Util.lean
+++ b/src/Lean/Meta/Tactic/Grind/Arith/Util.lean
@@ -1,102 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Lean.Expr
-import Lean.Message
-
-namespace Lean.Meta.Grind.Arith
-
-/-- Returns `true` if `e` is of the form `Nat` -/
-def isNatType (e : Expr) : Bool :=
-  e.isConstOf ``Nat
-
-/-- Returns `true` if `e` is of the form `@instHAdd Nat instAddNat` -/
-def isInstAddNat (e : Expr) : Bool :=
-  let_expr instHAdd a b := e | false
-  isNatType a && b.isConstOf ``instAddNat
-
-/-- Returns `true` if `e` is `instLENat` -/
-def isInstLENat (e : Expr) : Bool :=
-  e.isConstOf ``instLENat
-
-/--
-Returns `some (a, b)` if `e` is of the form
-```
-@HAdd.hAdd Nat Nat Nat (instHAdd Nat instAddNat) a b
-```
-/
-def isNatAdd? (e : Expr) : Option (Expr × Expr) :=
-  let_expr HAdd.hAdd _ _ _ i a b := e | none
-  if isInstAddNat i then some (a, b) else none
-
-/--
-Returns `true` if `e` is of the form
-```
-@HAdd.hAdd Nat Nat Nat (instHAdd Nat instAddNat) _ _
-```
-/
-def isNatAdd (e : Expr) : Bool :=
-  let_expr HAdd.hAdd _ _ _ i _ _ := e | false
-  isInstAddNat i
-
-/-- Returns `some k` if `e` `@OfNat.ofNat Nat _ (instOfNatNat k)` -/
-def isNatNum? (e : Expr) : Option Nat := Id.run do
-  let_expr OfNat.ofNat _ _ inst := e | none
-  let_expr instOfNatNat k := inst | none
-  let .lit (.natVal k) := k | none
-  some k
-
-/-- Returns `some (a, k)` if `e` is of the form `a + k`.  -/
-def isNatOffset? (e : Expr) : Option (Expr × Nat) := Id.run do
-  let some (a, b) := isNatAdd? e | none
-  let some k := isNatNum? b | none
-  some (a, k)
-
-/-- An offset constraint. -/
-structure Offset.Cnstr (α : Type) where
-  u  : α
-  v  : α
-  k  : Int := 0
-  deriving Inhabited
-
-def Offset.Cnstr.neg : Cnstr α → Cnstr α
-  | { u, v, k } => { u := v, v := u, k := -k - 1 }
-
-example (c : Offset.Cnstr α) : c.neg.neg = c := by
-  cases c; simp [Offset.Cnstr.neg]; omega
-
-def Offset.toMessageData [inst : ToMessageData α] (c : Offset.Cnstr α) : MessageData :=
-  match c.k with
-  | .ofNat 0   => m!"{c.u} ≤ {c.v}"
-  | .ofNat k   => m!"{c.u} ≤ {c.v} + {k}"
-  | .negSucc k => m!"{c.u} + {k + 1} ≤ {c.v}"
-
-instance : ToMessageData (Offset.Cnstr Expr) where
-  toMessageData c := Offset.toMessageData c
-
-/--
-Returns `some cnstr` if `e` is offset constraint.
-Remark: `z` is `0` numeral. It is an extra argument because we
-want to be able to provide the one that has already been internalized.
-/
-def isNatOffsetCnstr? (e : Expr) (z : Expr) : Option (Offset.Cnstr Expr) :=
-  match_expr e with
-  | LE.le _ inst a b => if isInstLENat inst then go a b else none
-  | _ => none
-where
-  go (u v : Expr) :=
-    if let some (u, k) := isNatOffset? u then
-      some { u, k := - k, v }
-    else if let some (v, k) := isNatOffset? v then
-      some { u, v, k }
-    else if let some k := isNatNum? u then
-      some { u := z, v, k := - k }
-    else if let some k := isNatNum? v then
-      some { u, v := z, k }
-    else
-      some { u, v }
-
-end Lean.Meta.Grind.Arith
--- a/src/Lean/Meta/Tactic/Grind/Canon.lean
+++ b/src/Lean/Meta/Tactic/Grind/Canon.lean
@@ -46,35 +46,15 @@ structure State where
  proofCanon : PHashMap Expr Expr := {}
  deriving Inhabited

-inductive CanonElemKind where
-  | /--
-    Type class instances are canonicalized using `TransparencyMode.instances`.
-    -/
-    instance
-  | /--
-    Types and Type formers are canonicalized using `TransparencyMode.default`.
-    Remark: propositions are just visited. We do not invoke `canonElemCore` for them.
-    -/
-    type
-  | /--
-    Implicit arguments that are not types, type formers, or instances, are canonicalized
-    using `TransparencyMode.reducible`
-    -/
-    implicit
-  deriving BEq
-
-def CanonElemKind.explain : CanonElemKind → String
-  | .instance => "type class instances"
-  | .type => "types (or type formers)"
-  | .implicit => "implicit arguments (which are not type class instances or types)"
-
 /--
 Helper function for canonicalizing `e` occurring as the `i`th argument of an `f`-application.
+`isInst` is true if `e` is an type class instance.

-Thus, if diagnostics are enabled, we also re-check them using `TransparencyMode.default`. If the result is different
+Recall that we use `TransparencyMode.instances` for checking whether two instances are definitionally equal or not.
+Thus, if diagnostics are enabled, we also check them using `TransparencyMode.default`. If the result is different
 we report to the user.
 -/
-def canonElemCore (f : Expr) (i : Nat) (e : Expr) (kind : CanonElemKind) : StateT State MetaM Expr := do
+def canonElemCore (f : Expr) (i : Nat) (e : Expr) (isInst : Bool) : StateT State MetaM Expr := do
  let s ← get
  if let some c := s.canon.find? e then
    return c
@@ -86,19 +66,16 @@ def canonElemCore (f : Expr) (i : Nat) (e : Expr) (kind : CanonElemKind) : State
      -- in general safe to replace `e` with `c` if `c` has more free variables than `e`.
      -- However, we don't revert previously canonicalized elements in the `grind` tactic.
      modify fun s => { s with canon := s.canon.insert e c }
-      trace[grind.debug.canon] "found {e} ===> {c}"
      return c
-    if kind != .type then
-      if (← isTracingEnabledFor `grind.issues <&&> (withDefault <| isDefEq e c)) then
+    if isInst then
+      if (← isDiagnosticsEnabled <&&> pure (c.fvarsSubset e) <&&> (withDefault <| isDefEq e c)) then
        -- TODO: consider storing this information in some structure that can be browsed later.
-        trace[grind.issues] "the following {kind.explain} are definitionally equal with `default` transparency but not with a more restrictive transparency{indentExpr e}\nand{indentExpr c}"
-  trace[grind.debug.canon] "({f}, {i}) ↦ {e}"
+        trace[grind.issues] "the following `grind` static elements are definitionally equal with `default` transparency, but not with `instances` transparency{indentExpr e}\nand{indentExpr c}"
  modify fun s => { s with canon := s.canon.insert e e, argMap := s.argMap.insert key (e::cs) }
  return e

-abbrev canonType (f : Expr) (i : Nat) (e : Expr) := withDefault <| canonElemCore f i e .type
-abbrev canonInst (f : Expr) (i : Nat) (e : Expr) := withReducibleAndInstances <| canonElemCore f i e .instance
-abbrev canonImplicit (f : Expr) (i : Nat) (e : Expr) := withReducible <| canonElemCore f i e .implicit
+abbrev canonType (f : Expr) (i : Nat) (e : Expr) := withDefault <| canonElemCore f i e false
+abbrev canonInst (f : Expr) (i : Nat) (e : Expr) := withReducibleAndInstances <| canonElemCore f i e true

 /--
 Return type for the `shouldCanon` function.
@@ -108,8 +85,6 @@ private inductive ShouldCanonResult where
    canonType
  | /- Nested instances are canonicalized. -/
    canonInst
-  | /- Implicit argument that is not an instance nor a type. -/
-    canonImplicit
  | /-
    Term is not a proof, type (former), nor an instance.
    Thus, it must be recursively visited by the canonizer.
@@ -117,13 +92,6 @@ private inductive ShouldCanonResult where
    visit
  deriving Inhabited

-instance : Repr ShouldCanonResult where
-  reprPrec r _ := match r with
-    | .canonType => "canonType"
-    | .canonInst => "canonInst"
-    | .canonImplicit => "canonImplicit"
-    | .visit => "visit"
-
 /--
 See comments at `ShouldCanonResult`.
 -/
@@ -134,14 +102,7 @@ def shouldCanon (pinfos : Array ParamInfo) (i : Nat) (arg : Expr) : MetaM Should
      return .canonInst
    else if pinfo.isProp then
      return .visit
-    else if pinfo.isImplicit then
-      if (← isTypeFormer arg) then
-        return .canonType
-      else
-        return .canonImplicit
-  if (← isProp arg) then
-    return .visit
-  else if (← isTypeFormer arg) then
+  if (← isTypeFormer arg) then
    return .canonType
  else
    return .visit
@@ -171,11 +132,9 @@ where
          let mut args := args.toVector
          for h : i in [:args.size] do
            let arg := args[i]
-            trace[grind.debug.canon] "[{repr (← shouldCanon pinfos i arg)}]: {arg} : {← inferType arg}"
            let arg' ← match (← shouldCanon pinfos i arg) with
            | .canonType  => canonType f i arg
            | .canonInst  => canonInst f i arg
-            | .canonImplicit => canonImplicit f i (← visit arg)
            | .visit      => visit arg
            unless ptrEq arg arg' do
              args := args.set i arg'
@@ -192,8 +151,7 @@ where
    return e'

 /-- Canonicalizes nested types, type formers, and instances in `e`. -/
-def canon (e : Expr) : StateT State MetaM Expr := do
-  trace[grind.debug.canon] "{e}"
+def canon (e : Expr) : StateT State MetaM Expr :=
  unsafe canonImpl e

 end Canon
--- a/src/Lean/Meta/Tactic/Grind/Core.lean
+++ b/src/Lean/Meta/Tactic/Grind/Core.lean
@@ -10,7 +10,6 @@ import Lean.Meta.Tactic.Grind.Types
 import Lean.Meta.Tactic.Grind.Inv
 import Lean.Meta.Tactic.Grind.PP
 import Lean.Meta.Tactic.Grind.Ctor
-import Lean.Meta.Tactic.Grind.Util
 import Lean.Meta.Tactic.Grind.Internalize

 namespace Lean.Meta.Grind
@@ -87,26 +86,6 @@ private partial def updateMT (root : Expr) : GoalM Unit := do
      setENode parent { node with mt := gmt }
      updateMT parent

-/--
-Helper function for combining `ENode.offset?` fields and propagating an equality
-to the offset constraint module.
-/
-private def propagateOffsetEq (rhsRoot lhsRoot : ENode) : GoalM Unit := do
-  match lhsRoot.offset? with
-  | some lhsOffset =>
-    if let some rhsOffset := rhsRoot.offset? then
-      Arith.processNewOffsetEq lhsOffset rhsOffset
-    else if isNatNum rhsRoot.self then
-      Arith.processNewOffsetEqLit lhsOffset rhsRoot.self
-    else
-      -- We have to retrieve the node because other fields have been updated
-      let rhsRoot ← getENode rhsRoot.self
-      setENode rhsRoot.self { rhsRoot with offset? := lhsOffset }
-  | none =>
-    if isNatNum lhsRoot.self then
-    if let some rhsOffset := rhsRoot.offset? then
-      Arith.processNewOffsetEqLit rhsOffset lhsRoot.self
-
 private partial def addEqStep (lhs rhs proof : Expr) (isHEq : Bool) : GoalM Unit := do
  let lhsNode ← getENode lhs
  let rhsNode ← getENode rhs
@@ -139,7 +118,7 @@ private partial def addEqStep (lhs rhs proof : Expr) (isHEq : Bool) : GoalM Unit
  unless (← isInconsistent) do
    if valueInconsistency then
      closeGoalWithValuesEq lhsRoot.self rhsRoot.self
-  trace_goal[grind.debug] "after addEqStep, {← (← get).ppState}"
+  trace_goal[grind.debug] "after addEqStep, {← ppState}"
  checkInvariants
 where
  go (lhs rhs : Expr) (lhsNode rhsNode lhsRoot rhsRoot : ENode) (flipped : Bool) : GoalM Unit := do
@@ -162,32 +141,31 @@ where
    updateRoots lhs rhsNode.root
    trace_goal[grind.debug] "{← ppENodeRef lhs} new root {← ppENodeRef rhsNode.root}, {← ppENodeRef (← getRoot lhs)}"
    reinsertParents parents
-    propagateEqcDown lhs
    setENode lhsNode.root { (← getENode lhsRoot.self) with -- We must retrieve `lhsRoot` since it was updated.
      next := rhsRoot.next
    }
    setENode rhsNode.root { rhsRoot with
-      next       := lhsRoot.next
-      size       := rhsRoot.size + lhsRoot.size
+      next := lhsRoot.next
+      size := rhsRoot.size + lhsRoot.size
      hasLambdas := rhsRoot.hasLambdas || lhsRoot.hasLambdas
      heqProofs  := isHEq || rhsRoot.heqProofs || lhsRoot.heqProofs
    }
    copyParentsTo parents rhsNode.root
-    unless (← isInconsistent) do
-      updateMT rhsRoot.self
-    propagateOffsetEq rhsRoot lhsRoot
    unless (← isInconsistent) do
      for parent in parents do
        propagateUp parent
+    unless (← isInconsistent) do
+      updateMT rhsRoot.self

  updateRoots (lhs : Expr) (rootNew : Expr) : GoalM Unit := do
-    traverseEqc lhs fun n =>
-      setENode n.self { n with root := rootNew }
-
-  propagateEqcDown (lhs : Expr) : GoalM Unit := do
-    traverseEqc lhs fun n =>
+    let rec loop (e : Expr) : GoalM Unit := do
+      let n ← getENode e
+      setENode e { n with root := rootNew }
      unless (← isInconsistent) do
-        propagateDown n.self
+        propagateDown e
+      if isSameExpr lhs n.next then return ()
+      loop n.next
+    loop lhs

 /-- Ensures collection of equations to be processed is empty. -/
 private def resetNewEqs : GoalM Unit :=
@@ -214,28 +192,22 @@ where
    processTodo

 /-- Adds a new equality `lhs = rhs`. It assumes `lhs` and `rhs` have already been internalized. -/
-private def addEq (lhs rhs proof : Expr) : GoalM Unit := do
+def addEq (lhs rhs proof : Expr) : GoalM Unit := do
  addEqCore lhs rhs proof false

-/-- Adds a new heterogeneous equality `HEq lhs rhs`. It assumes `lhs` and `rhs` have already been internalized. -/
-private def addHEq (lhs rhs proof : Expr) : GoalM Unit := do
-  addEqCore lhs rhs proof true

-/-- Save asserted facts for pretty printing goal. -/
-private def storeFact (fact : Expr) : GoalM Unit := do
-  modify fun s => { s with facts := s.facts.push fact }
+/-- Adds a new heterogeneous equality `HEq lhs rhs`. It assumes `lhs` and `rhs` have already been internalized. -/
+def addHEq (lhs rhs proof : Expr) : GoalM Unit := do
+  addEqCore lhs rhs proof true

 /-- Internalizes `lhs` and `rhs`, and then adds equality `lhs = rhs`. -/
 def addNewEq (lhs rhs proof : Expr) (generation : Nat) : GoalM Unit := do
-  let eq ← mkEq lhs rhs
-  storeFact eq
-  internalize lhs generation eq
-  internalize rhs generation eq
+  internalize lhs generation
+  internalize rhs generation
  addEq lhs rhs proof

 /-- Adds a new `fact` justified by the given proof and using the given generation. -/
 def add (fact : Expr) (proof : Expr) (generation := 0) : GoalM Unit := do
-  storeFact fact
  trace_goal[grind.assert] "{fact}"
  if (← isInconsistent) then return ()
  resetNewEqs
@@ -245,30 +217,22 @@ def add (fact : Expr) (proof : Expr) (generation := 0) : GoalM Unit := do
 where
  go (p : Expr) (isNeg : Bool) : GoalM Unit := do
    match_expr p with
-    | Eq α lhs rhs =>
-      if α.isProp then
-        -- It is morally an iff.
-        -- We do not use the `goEq` optimization because we want to register `p` as a case-split
-        goFact p isNeg
-      else
-        goEq p lhs rhs isNeg false
+    | Eq _ lhs rhs => goEq p lhs rhs isNeg false
    | HEq _ lhs _ rhs => goEq p lhs rhs isNeg true
-    | _ => goFact p isNeg
-
-  goFact (p : Expr) (isNeg : Bool) : GoalM Unit := do
-    internalize p generation
-    if isNeg then
-      addEq p (← getFalseExpr) (← mkEqFalse proof)
-    else
-      addEq p (← getTrueExpr) (← mkEqTrue proof)
+    | _ =>
+      internalize p generation
+      if isNeg then
+        addEq p (← getFalseExpr) (← mkEqFalse proof)
+      else
+        addEq p (← getTrueExpr) (← mkEqTrue proof)

  goEq (p : Expr) (lhs rhs : Expr) (isNeg : Bool) (isHEq : Bool) : GoalM Unit := do
    if isNeg then
      internalize p generation
      addEq p (← getFalseExpr) (← mkEqFalse proof)
    else
-      internalize lhs generation p
-      internalize rhs generation p
+      internalize lhs generation
+      internalize rhs generation
      addEqCore lhs rhs proof isHEq

 /-- Adds a new hypothesis. -/
--- a/src/Lean/Meta/Tactic/Grind/EMatchTheorem.lean
+++ b/src/Lean/Meta/Tactic/Grind/EMatchTheorem.lean
@@ -57,8 +57,7 @@ inductive Origin where
  is the provided grind argument. The `id` is a unique identifier for the call.
  -/
  | stx (id : Name) (ref : Syntax)
-  /-- It is local, but we don't have a local hypothesis for it. -/
-  | local (id : Name)
+  | other (id : Name)
  deriving Inhabited, Repr, BEq

 /-- A unique identifier corresponding to the origin. -/
@@ -66,14 +65,14 @@ def Origin.key : Origin → Name
  | .decl declName => declName
  | .fvar fvarId   => fvarId.name
  | .stx id _      => id
-  | .local id      => id
+  | .other id      => id

 def Origin.pp [Monad m] [MonadEnv m] [MonadError m] (o : Origin) : m MessageData := do
  match o with
  | .decl declName => return MessageData.ofConst (← mkConstWithLevelParams declName)
  | .fvar fvarId   => return mkFVar fvarId
  | .stx _ ref     => return ref
-  | .local id      => return id
+  | .other id      => return id

 instance : BEq Origin where
  beq a b := a.key == b.key
@@ -170,43 +169,11 @@ private builtin_initialize ematchTheoremsExt : SimpleScopedEnvExtension EMatchTh
    initial  := {}
  }

-/--
-Symbols with built-in support in `grind` are unsuitable as pattern candidates for E-matching.
-This is because `grind` performs normalization operations and uses specialized data structures
-to implement these symbols, which may interfere with E-matching behavior.
-/
 -- TODO: create attribute?
 private def forbiddenDeclNames := #[``Eq, ``HEq, ``Iff, ``And, ``Or, ``Not]

 private def isForbidden (declName : Name) := forbiddenDeclNames.contains declName

-/--
-Auxiliary function to expand a pattern containing forbidden application symbols
-into a multi-pattern.
-
-This function enhances the usability of the `[grind =]` attribute by automatically handling
-forbidden pattern symbols. For example, consider the following theorem tagged with this attribute:
-```
-getLast?_eq_some_iff {xs : List α} {a : α} : xs.getLast? = some a ↔ ∃ ys, xs = ys ++ [a]
-```
-Here, the selected pattern is `xs.getLast? = some a`, but `Eq` is a forbidden pattern symbol.
-Instead of producing an error, this function converts the pattern into a multi-pattern,
-allowing the attribute to be used conveniently.
-
-The function recursively expands patterns with forbidden symbols by splitting them
-into their sub-components. If the pattern does not contain forbidden symbols,
-it is returned as-is.
-/
-partial def splitWhileForbidden (pat : Expr) : List Expr :=
-  match_expr pat with
-  | Not p => splitWhileForbidden p
-  | And p₁ p₂ => splitWhileForbidden p₁ ++ splitWhileForbidden p₂
-  | Or p₁ p₂ => splitWhileForbidden p₁ ++ splitWhileForbidden p₂
-  | Eq _ lhs rhs => splitWhileForbidden lhs ++ splitWhileForbidden rhs
-  | Iff lhs rhs => splitWhileForbidden lhs ++ splitWhileForbidden rhs
-  | HEq _ lhs _ rhs => splitWhileForbidden lhs ++ splitWhileForbidden rhs
-  | _ => [pat]
-
 private def dontCare := mkConst (Name.mkSimple "[grind_dontcare]")

 def mkGroundPattern (e : Expr) : Expr :=
@@ -500,8 +467,7 @@ def mkEMatchEqTheoremCore (origin : Origin) (levelParams : Array Name) (proof :
      | _ => throwError "invalid E-matching equality theorem, conclusion must be an equality{indentExpr type}"
    let pat := if useLhs then lhs else rhs
    let pat ← preprocessPattern pat normalizePattern
-    let pats := splitWhileForbidden (pat.abstract xs)
-    return (xs.size, pats)
+    return (xs.size, [pat.abstract xs])
  mkEMatchTheoremCore origin levelParams numParams proof patterns

 /--
@@ -532,7 +498,7 @@ def addEMatchEqTheorem (declName : Name) : MetaM Unit := do
 def getEMatchTheorems : CoreM EMatchTheorems :=
  return ematchTheoremsExt.getState (← getEnv)

-inductive TheoremKind where
+private inductive TheoremKind where
  | eqLhs | eqRhs | eqBoth | fwd | bwd | default
  deriving Inhabited, BEq

@@ -632,7 +598,7 @@ private def collectPatterns? (proof : Expr) (xs : Array Expr) (searchPlaces : Ar
    | return none
  return some (ps, s.symbols.toList)

-def mkEMatchTheoremWithKind? (origin : Origin) (levelParams : Array Name) (proof : Expr) (kind : TheoremKind) : MetaM (Option EMatchTheorem) := do
+private def mkEMatchTheoremWithKind? (origin : Origin) (levelParams : Array Name) (proof : Expr) (kind : TheoremKind) : MetaM (Option EMatchTheorem) := do
  if kind == .eqLhs then
    return (← mkEMatchEqTheoremCore origin levelParams proof (normalizePattern := false) (useLhs := true))
  else if kind == .eqRhs then
--- a/src/Lean/Meta/Tactic/Grind/ENodeKey.lean
+++ b/src/Lean/Meta/Tactic/Grind/ENodeKey.lean
@@ -1,30 +0,0 @@
-/-
-Copyright (c) 2025 Amazon.com, Inc. or its affiliates. All Rights Reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Leonardo de Moura
-/
-prelude
-import Lean.Expr
-
-namespace Lean.Meta.Grind
-
-@[inline] def isSameExpr (a b : Expr) : Bool :=
-  -- It is safe to use pointer equality because we hashcons all expressions
-  -- inserted into the E-graph
-  unsafe ptrEq a b
-
-/--
-Key for the `ENodeMap` and `ParentMap` map.
-We use pointer addresses and rely on the fact all internalized expressions
-have been hash-consed, i.e., we have applied `shareCommon`.
-/
-structure ENodeKey where
-  expr : Expr
-
-instance : Hashable ENodeKey where
-  hash k := unsafe (ptrAddrUnsafe k.expr).toUInt64
-
-instance : BEq ENodeKey where
-  beq k₁ k₂ := isSameExpr k₁.expr k₂.expr
-
-end Lean.Meta.Grind
--- a/src/Lean/Meta/Tactic/Grind/ForallProp.lean
+++ b/src/Lean/Meta/Tactic/Grind/ForallProp.lean
@@ -24,7 +24,7 @@ def propagateForallPropUp (e : Expr) : GoalM Unit := do
    unless (← isEqTrue p) do return
    trace_goal[grind.debug.forallPropagator] "isEqTrue, {e}"
    let h₁ ← mkEqTrueProof p
-    let qh₁ := q.instantiate1 (mkOfEqTrueCore p h₁)
+    let qh₁ := q.instantiate1 (mkApp2 (mkConst ``of_eq_true) p h₁)
    let r ← simp qh₁
    let q := mkLambda n bi p q
    let q' := r.expr
@@ -46,39 +46,6 @@ where
      -- b = True → (a → b) = True
      pushEqTrue e <| mkApp3 (mkConst ``Grind.imp_eq_of_eq_true_right) a b (← mkEqTrueProof b)

-private def isEqTrueHyp? (proof : Expr) : Option FVarId := Id.run do
-  let_expr eq_true _ p := proof | return none
-  let .fvar fvarId := p | return none
-  return some fvarId
-
-/-- Similar to `mkEMatchTheoremWithKind?`, but swallow any exceptions. -/
-private def mkEMatchTheoremWithKind'? (origin : Origin) (proof : Expr) (kind : TheoremKind) : MetaM (Option EMatchTheorem) := do
-  try
-    mkEMatchTheoremWithKind? origin #[] proof kind
-  catch _ =>
-    return none
-
-private def addLocalEMatchTheorems (e : Expr) : GoalM Unit := do
-  let proof ← mkEqTrueProof e
-  let origin ← if let some fvarId := isEqTrueHyp? proof then
-    pure <| .fvar fvarId
-  else
-    let idx ← modifyGet fun s => (s.nextThmIdx, { s with nextThmIdx := s.nextThmIdx + 1 })
-    pure <| .local ((`local).appendIndexAfter idx)
-  let proof := mkOfEqTrueCore e proof
-  let size := (← get).newThms.size
-  let gen ← getGeneration e
-  -- TODO: we should have a flag for collecting all unary patterns in a local theorem
-  if let some thm ← mkEMatchTheoremWithKind'? origin proof .fwd then
-    activateTheorem thm gen
-  if let some thm ← mkEMatchTheoremWithKind'? origin proof .bwd then
-    activateTheorem thm gen
-  if (← get).newThms.size == size then
-    if let some thm ← mkEMatchTheoremWithKind'? origin proof .default then
-      activateTheorem thm gen
-  if (← get).newThms.size == size then
-    trace[grind.issues] "failed to create E-match local theorem for{indentExpr e}"
-
 def propagateForallPropDown (e : Expr) : GoalM Unit := do
  let .forallE n a b bi := e | return ()
  if (← isEqFalse e) then
@@ -95,8 +62,5 @@ def propagateForallPropDown (e : Expr) : GoalM Unit := do
      let h ← mkEqFalseProof e
      pushEqTrue a <| mkApp3 (mkConst ``Grind.eq_true_of_imp_eq_false) a b h
      pushEqFalse b <| mkApp3 (mkConst ``Grind.eq_false_of_imp_eq_false) a b h
-  else if (← isEqTrue e) then
-    if b.hasLooseBVars then
-      addLocalEMatchTheorems e

 end Lean.Meta.Grind
--- a/src/Lean/Meta/Tactic/Grind/Internalize.lean
+++ b/src/Lean/Meta/Tactic/Grind/Internalize.lean
@@ -11,7 +11,6 @@ import Lean.Meta.Match.MatcherInfo
 import Lean.Meta.Match.MatchEqsExt
 import Lean.Meta.Tactic.Grind.Types
 import Lean.Meta.Tactic.Grind.Util
-import Lean.Meta.Tactic.Grind.Arith.Internalize

 namespace Lean.Meta.Grind

@@ -54,36 +53,25 @@ private def addSplitCandidate (e : Expr) : GoalM Unit := do
 -- TODO: add attribute to make this extensible
 private def forbiddenSplitTypes := [``Eq, ``HEq, ``True, ``False]

-/-- Returns `true` if `e` is of the form `@Eq Prop a b` -/
-def isMorallyIff (e : Expr) : Bool :=
-  let_expr Eq α _ _ := e | false
-  α.isProp
-
 /-- Inserts `e` into the list of case-split candidates if applicable. -/
 private def checkAndAddSplitCandidate (e : Expr) : GoalM Unit := do
  unless e.isApp do return ()
-  if (← getConfig).splitIte && (e.isIte || e.isDIte) then
+  if e.isIte || e.isDIte then
    addSplitCandidate e
-    return ()
-  if isMorallyIff e then
-    addSplitCandidate e
-    return ()
-  if (← getConfig).splitMatch then
-    if (← isMatcherApp e) then
-      if let .reduced _ ← reduceMatcher? e then
-        -- When instantiating `match`-equations, we add `match`-applications that can be reduced,
-        -- and consequently don't need to be splitted.
-        return ()
-      else
-        addSplitCandidate e
-        return ()
-  let .const declName _  := e.getAppFn | return ()
+  else if (← isMatcherApp e) then
+    if let .reduced _ ← reduceMatcher? e then
+      -- When instantiating `match`-equations, we add `match`-applications that can be reduced,
+      -- and consequently don't need to be splitted.
+      return ()
+    else
+      addSplitCandidate e
+  else
+    let .const declName _  := e.getAppFn | return ()
    if forbiddenSplitTypes.contains declName then return ()
    -- We should have a mechanism for letting users to select types to case-split.
    -- Right now, we just consider inductive predicates that are not in the forbidden list
-    if (← getConfig).splitIndPred then
-      if (← isInductivePredicate declName) then
-        addSplitCandidate e
+    if (← isInductivePredicate declName) then
+      addSplitCandidate e

 /--
 If `e` is a `cast`-like term (e.g., `cast h a`), add `HEq e a` to the to-do list.
@@ -105,12 +93,12 @@ private partial def internalizePattern (pattern : Expr) (generation : Nat) : Goa
    return pattern
  else if let some e := groundPattern? pattern then
    let e ← shareCommon (← canon (← normalizeLevels (← unfoldReducible e)))
-    internalize e generation none
+    internalize e generation
    return mkGroundPattern e
  else pattern.withApp fun f args => do
    return mkAppN f (← args.mapM (internalizePattern · generation))

-partial def activateTheorem (thm : EMatchTheorem) (generation : Nat) : GoalM Unit := do
+private partial def activateTheorem (thm : EMatchTheorem) (generation : Nat) : GoalM Unit := do
  -- Recall that we use the proof as part of the key for a set of instances found so far.
  -- We don't want to use structural equality when comparing keys.
  let proof ← shareCommon thm.proof
@@ -146,7 +134,7 @@ private partial def activateTheoremPatterns (fName : Name) (generation : Nat) :
          trace_goal[grind.ematch] "reinsert `{thm.origin.key}`"
          modify fun s => { s with thmMap := s.thmMap.insert thm }

-partial def internalize (e : Expr) (generation : Nat) (parent? : Option Expr := none) : GoalM Unit := do
+partial def internalize (e : Expr) (generation : Nat) : GoalM Unit := do
  if (← alreadyInternalized e) then return ()
  trace_goal[grind.internalize] "{e}"
  match e with
@@ -157,10 +145,10 @@ partial def internalize (e : Expr) (generation : Nat) (parent? : Option Expr :=
  | .forallE _ d b _ =>
    mkENodeCore e (ctor := false) (interpreted := false) (generation := generation)
    if (← isProp d <&&> isProp e) then
-      internalize d generation e
+      internalize d generation
      registerParent e d
      unless b.hasLooseBVars do
-        internalize b generation e
+        internalize b generation
        registerParent e b
      propagateUp e
  | .lit .. | .const .. =>
@@ -174,7 +162,6 @@ partial def internalize (e : Expr) (generation : Nat) (parent? : Option Expr :=
    if (← isLitValue e) then
      -- We do not want to internalize the components of a literal value.
      mkENode e generation
-      Arith.internalize e parent?
    else e.withApp fun f args => do
      checkAndAddSplitCandidate e
      pushCastHEqs e
@@ -183,22 +170,21 @@ partial def internalize (e : Expr) (generation : Nat) (parent? : Option Expr :=
        -- We only internalize the proposition. We can skip the proof because of
        -- proof irrelevance
        let c := args[0]!
-        internalize c generation e
+        internalize c generation
        registerParent e c
      else
        if let .const fName _ := f then
          activateTheoremPatterns fName generation
        else
-          internalize f generation e
+          internalize f generation
          registerParent e f
        for h : i in [: args.size] do
          let arg := args[i]
-          internalize arg generation e
+          internalize arg generation
          registerParent e arg
      mkENode e generation
      addCongrTable e
      updateAppMap e
-      Arith.internalize e parent?
      propagateUp e
 end

--- a/src/Lean/Meta/Tactic/Grind/Inv.lean
+++ b/src/Lean/Meta/Tactic/Grind/Inv.lean
@@ -6,7 +6,6 @@ Authors: Leonardo de Moura
 prelude
 import Lean.Meta.Tactic.Grind.Types
 import Lean.Meta.Tactic.Grind.Proof
-import Lean.Meta.Tactic.Grind.Arith.Inv

 namespace Lean.Meta.Grind

@@ -59,12 +58,9 @@ private def checkParents (e : Expr) : GoalM Unit := do
          found := true
          break
      -- Recall that we have support for `Expr.forallE` propagation. See `ForallProp.lean`.
-      if let .forallE _ d b _ := parent then
+      if let .forallE _ d _ _ := parent then
        if (← checkChild d) then
          found := true
-        unless b.hasLooseBVars do
-          if (← checkChild b) then
-            found := true
      unless found do
        assert! (← checkChild parent.getAppFn)
  else
@@ -104,7 +100,6 @@ def checkInvariants (expensive := false) : GoalM Unit := do
        checkEqc node
    if expensive then
      checkPtrEqImpliesStructEq
-    Arith.checkInvariants
  if expensive && grind.debug.proofs.get (← getOptions) then
    checkProofs

--- a/src/Lean/Meta/Tactic/Grind/Main.lean
+++ b/src/Lean/Meta/Tactic/Grind/Main.lean
@@ -40,20 +40,17 @@ def GrindM.run (x : GrindM α) (mainDeclName : Name) (config : Grind.Config) (fa
  let scState := ShareCommon.State.mk _
  let (falseExpr, scState) := ShareCommon.State.shareCommon scState (mkConst ``False)
  let (trueExpr, scState)  := ShareCommon.State.shareCommon scState (mkConst ``True)
-  let (natZExpr, scState)  := ShareCommon.State.shareCommon scState (mkNatLit 0)
  let simprocs ← Grind.getSimprocs
  let simp ← Grind.getSimpContext
-  x (← mkMethods fallback).toMethodsRef { mainDeclName, config, simprocs, simp } |>.run' { scState, trueExpr, falseExpr, natZExpr }
+  x (← mkMethods fallback).toMethodsRef { mainDeclName, config, simprocs, simp } |>.run' { scState, trueExpr, falseExpr }

 private def mkGoal (mvarId : MVarId) : GrindM Goal := do
  let trueExpr ← getTrueExpr
  let falseExpr ← getFalseExpr
-  let natZeroExpr ← getNatZeroExpr
  let thmMap ← getEMatchTheorems
  GoalM.run' { mvarId, thmMap } do
    mkENodeCore falseExpr (interpreted := true) (ctor := false) (generation := 0)
    mkENodeCore trueExpr (interpreted := true) (ctor := false) (generation := 0)
-    mkENodeCore natZeroExpr (interpreted := true) (ctor := false) (generation := 0)

 private def initCore (mvarId : MVarId) : GrindM (List Goal) := do
  mvarId.ensureProp
@@ -75,8 +72,8 @@ def all (goals : List Goal) (f : Goal → GrindM (List Goal)) : GrindM (List Goa
 private def simple (goals : List Goal) : GrindM (List Goal) := do
  applyToAll (assertAll >> ematchStar >> (splitNext >> assertAll >> ematchStar).iterate) goals

-def main (mvarId : MVarId) (config : Grind.Config) (mainDeclName : Name) (fallback : Fallback) : MetaM (List Goal) := do
-  let go : GrindM (List Goal) := do
+def main (mvarId : MVarId) (config : Grind.Config) (mainDeclName : Name) (fallback : Fallback) : MetaM (List MVarId) := do
+  let go : GrindM (List MVarId) := do
    let goals ← initCore mvarId
    let goals ← simple goals
    let goals ← goals.filterMapM fun goal => do
@@ -86,7 +83,7 @@ def main (mvarId : MVarId) (config : Grind.Config) (mainDeclName : Name) (fallba
      if (← goal.mvarId.isAssigned) then return none
      return some goal
    trace[grind.debug.final] "{← ppGoals goals}"
-    return goals
+    return goals.map (·.mvarId)
  go.run mainDeclName config fallback

 end Lean.Meta.Grind
--- a/src/Lean/Meta/Tactic/Grind/PP.lean
+++ b/src/Lean/Meta/Tactic/Grind/PP.lean
@@ -5,132 +5,62 @@ Authors: Leonardo de Moura
 -/
 prelude
 import Init.Grind.Util
-import Init.Grind.PP
 import Lean.Meta.Tactic.Grind.Types
-import Lean.Meta.Tactic.Grind.Arith.Model

 namespace Lean.Meta.Grind

 /-- Helper function for pretty printing the state for debugging purposes. -/
-def Goal.ppENodeRef (goal : Goal) (e : Expr) : MetaM MessageData := do
-  let some n := goal.getENode? e | return "_"
-  let type ← inferType e
-  let u ← getLevel type
-  let d := mkApp3 (mkConst ``Grind.node_def [u]) (toExpr n.idx) type e
-  return m!"{d}"
-
-@[inherit_doc Goal.ppENodeRef]
-def ppENodeRef (e : Expr) : GoalM MessageData := do
-  (← get).ppENodeRef e
+def ppENodeRef (e : Expr) : GoalM Format := do
+  let some n ← getENode? e | return "_"
+  return f!"#{n.idx}"

 /-- Helper function for pretty printing the state for debugging purposes. -/
-private def Goal.ppENodeDeclValue (goal : Goal) (e : Expr) : MetaM MessageData := do
+def ppENodeDeclValue (e : Expr) : GoalM Format := do
  if e.isApp && !(← isLitValue e) then
    e.withApp fun f args => do
      let r ← if f.isConst then
-        pure m!"{f}"
+        ppExpr f
      else
-        goal.ppENodeRef f
+        ppENodeRef f
      let mut r := r
      for arg in args do
-        r := r ++ " " ++ (← goal.ppENodeRef arg)
+        r := r ++ " " ++ (← ppENodeRef arg)
      return r
  else
    ppExpr e

 /-- Helper function for pretty printing the state for debugging purposes. -/
-private def Goal.ppENodeDecl (goal : Goal) (e : Expr) : MetaM MessageData := do
-  let mut r := m!"{← goal.ppENodeRef e} := {← goal.ppENodeDeclValue e}"
-  let n ← goal.getENode e
+def ppENodeDecl (e : Expr) : GoalM Format := do
+  let mut r := f!"{← ppENodeRef e} := {← ppENodeDeclValue e}"
+  let n ← getENode e
  unless isSameExpr e n.root do
-    r := r ++ m!" ↦ {← goal.ppENodeRef n.root}"
+    r := r ++ f!" ↦ {← ppENodeRef n.root}"
  if n.interpreted then
    r := r ++ ", [val]"
  if n.ctor then
    r := r ++ ", [ctor]"
  if grind.debug.get (← getOptions) then
-    if let some target := goal.getTarget? e then
-      r := r ++ m!" ↝ {← goal.ppENodeRef target}"
+    if let some target ← getTarget? e then
+      r := r ++ f!" ↝ {← ppENodeRef target}"
  return r

 /-- Pretty print goal state for debugging purposes. -/
-def Goal.ppState (goal : Goal) : MetaM MessageData := do
-  let mut r := m!"Goal:"
-  let nodes := goal.getENodes
+def ppState : GoalM Format := do
+  let mut r := f!"Goal:"
+  let nodes ← getENodes
  for node in nodes do
-    r := r ++ "\n" ++ (← goal.ppENodeDecl node.self)
-  let eqcs := goal.getEqcs
+    r := r ++ "\n" ++ (← ppENodeDecl node.self)
+  let eqcs ← getEqcs
  for eqc in eqcs do
    if eqc.length > 1 then
-      r := r ++ "\n" ++ "{" ++ (MessageData.joinSep (← eqc.mapM goal.ppENodeRef) ", ") ++  "}"
+      r := r ++ "\n" ++ "{" ++ (Format.joinSep (← eqc.mapM ppENodeRef) ", ") ++  "}"
  return r

-def ppGoals (goals : List Goal) : MetaM MessageData := do
-  let mut r := m!""
+def ppGoals (goals : List Goal) : GrindM Format := do
+  let mut r := f!""
  for goal in goals do
-    let m ← goal.ppState
-    r := r ++ Format.line ++ m
+    let (f, _) ← GoalM.run goal ppState
+    r := r ++ Format.line ++ f
  return r

-private def ppExprArray (cls : Name) (header : String) (es : Array Expr) (clsElem : Name := Name.mkSimple "_") : MessageData :=
-  let es := es.map fun e => .trace { cls := clsElem} m!"{e}" #[]
-  .trace { cls } header es
-
-private def ppEqcs (goal : Goal) : MetaM (Array MessageData) := do
-   let mut trueEqc?  : Option MessageData := none
-   let mut falseEqc? : Option MessageData := none
-   let mut otherEqcs : Array MessageData := #[]
-   for eqc in goal.getEqcs do
-     if Option.isSome <| eqc.find? (·.isTrue) then
-       let eqc := eqc.filter fun e => !e.isTrue
-       unless eqc.isEmpty do
-         trueEqc? := ppExprArray `eqc "True propositions" eqc.toArray `prop
-     else if Option.isSome <| eqc.find? (·.isFalse) then
-       let eqc := eqc.filter fun e => !e.isFalse
-       unless eqc.isEmpty do
-         falseEqc? := ppExprArray `eqc "False propositions" eqc.toArray `prop
-     else if let e :: _ :: _ := eqc then
-       -- We may want to add a flag to pretty print equivalence classes of nested proofs
-       unless (← isProof e) do
-         otherEqcs := otherEqcs.push <| .trace { cls := `eqc } (.group ("{" ++ (MessageData.joinSep (eqc.map toMessageData) ("," ++ Format.line)) ++  "}")) #[]
-   let mut result := #[]
-   if let some trueEqc := trueEqc? then result := result.push trueEqc
-   if let some falseEqc := falseEqc? then result := result.push falseEqc
-   unless otherEqcs.isEmpty do
-     result := result.push <| .trace { cls := `eqc } "Equivalence classes" otherEqcs
-   return result
-
-private def ppEMatchTheorem (thm : EMatchTheorem) : MetaM MessageData := do
-  let m := m!"{← thm.origin.pp}\n{← inferType thm.proof}\npatterns: {thm.patterns.map ppPattern}"
-  return .trace { cls := `thm } m #[]
-
-private def ppActiveTheorems (goal : Goal) : MetaM MessageData := do
-  let m ← goal.thms.toArray.mapM ppEMatchTheorem
-  let m := m ++ (← goal.newThms.toArray.mapM ppEMatchTheorem)
-  if m.isEmpty then
-    return ""
-  else
-    return .trace { cls := `ematch } "E-matching" m
-
-def ppOffset (goal : Goal) : MetaM MessageData := do
-  let s := goal.arith.offset
-  let nodes := s.nodes
-  if nodes.isEmpty then return ""
-  let model ← Arith.Offset.mkModel goal
-  let mut ms := #[]
-  for (e, val) in model do
-    ms := ms.push <| .trace { cls := `assign } m!"{e} := {val}" #[]
-  return .trace { cls := `offset } "Assignment satisfying offset contraints" ms
-
-def goalToMessageData (goal : Goal) : MetaM MessageData := goal.mvarId.withContext do
-  let mut m : Array MessageData := #[.ofGoal goal.mvarId]
-  m := m.push <| ppExprArray `facts "Asserted facts" goal.facts.toArray `prop
-  m := m ++ (← ppEqcs goal)
-  m := m.push (← ppActiveTheorems goal)
-  m := m.push (← ppOffset goal)
-  addMessageContextFull <| MessageData.joinSep m.toList ""
-
-def goalsToMessageData (goals : List Goal) : MetaM MessageData :=
-  return MessageData.joinSep (← goals.mapM goalToMessageData) m!"\n"
-
 end Lean.Meta.Grind
--- a/src/Lean/Meta/Tactic/Grind/Propagate.lean
+++ b/src/Lean/Meta/Tactic/Grind/Propagate.lean
@@ -126,32 +126,32 @@ builtin_grind_propagator propagateEqUp ↑Eq := fun e => do
  else if (← isEqTrue b) then
    pushEq e a <| mkApp3 (mkConst ``Lean.Grind.eq_eq_of_eq_true_right) a b (← mkEqTrueProof b)
  else if (← isEqv a b) then
-    pushEqTrue e <| mkEqTrueCore e (← mkEqProof a b)
+    pushEqTrue e <| mkApp2 (mkConst ``eq_true) e (← mkEqProof a b)

 /-- Propagates `Eq` downwards -/
 builtin_grind_propagator propagateEqDown ↓Eq := fun e => do
  if (← isEqTrue e) then
    let_expr Eq _ a b := e | return ()
-    pushEq a b <| mkOfEqTrueCore e (← mkEqTrueProof e)
+    pushEq a b <| mkApp2 (mkConst ``of_eq_true) e (← mkEqTrueProof e)

 /-- Propagates `EqMatch` downwards -/
 builtin_grind_propagator propagateEqMatchDown ↓Grind.EqMatch := fun e => do
  if (← isEqTrue e) then
    let_expr Grind.EqMatch _ a b origin := e | return ()
    markCaseSplitAsResolved origin
-    pushEq a b <| mkOfEqTrueCore e (← mkEqTrueProof e)
+    pushEq a b <| mkApp2 (mkConst ``of_eq_true) e (← mkEqTrueProof e)

 /-- Propagates `HEq` downwards -/
 builtin_grind_propagator propagateHEqDown ↓HEq := fun e => do
  if (← isEqTrue e) then
    let_expr HEq _ a _ b := e | return ()
-    pushHEq a b <| mkOfEqTrueCore e (← mkEqTrueProof e)
+    pushHEq a b <| mkApp2 (mkConst ``of_eq_true) e (← mkEqTrueProof e)

 /-- Propagates `HEq` upwards -/
 builtin_grind_propagator propagateHEqUp ↑HEq := fun e => do
  let_expr HEq _ a _ b := e | return ()
  if (← isEqv a b) then
-    pushEqTrue e <| mkEqTrueCore e (← mkHEqProof a b)
+    pushEqTrue e <| mkApp2 (mkConst ``eq_true) e (← mkHEqProof a b)

 /-- Propagates `ite` upwards -/
 builtin_grind_propagator propagateIte ↑ite := fun e => do
@@ -166,7 +166,7 @@ builtin_grind_propagator propagateDIte ↑dite := fun e => do
  let_expr f@dite α c h a b := e | return ()
  if (← isEqTrue c) then
     let h₁ ← mkEqTrueProof c
-     let ah₁ := mkApp a (mkOfEqTrueCore c h₁)
+     let ah₁ := mkApp a (mkApp2 (mkConst ``of_eq_true) c h₁)
     let p ← simp ah₁
     let r := p.expr
     let h₂ ← p.getProof
--- a/src/Lean/Meta/Tactic/Grind/Split.lean
+++ b/src/Lean/Meta/Tactic/Grind/Split.lean
@@ -14,123 +14,77 @@ namespace Lean.Meta.Grind
 inductive CaseSplitStatus where
  | resolved
  | notReady
-  | ready (numCases : Nat) (isRec := false)
+  | ready
  deriving Inhabited, BEq

-/-- Given `c`, the condition of an `if-then-else`, check whether we need to case-split on the `if-then-else` or not -/
-private def checkIteCondStatus (c : Expr) : GoalM CaseSplitStatus := do
-  if (← isEqTrue c <||> isEqFalse c) then
-    return .resolved
-  else
-    return .ready 2
-
-/--
-Given `e` of the form `a ∨ b`, check whether we are ready to case-split on `e`.
-That is, `e` is `True`, but neither `a` nor `b` is `True`."
-/
-private def checkDisjunctStatus (e a b : Expr) : GoalM CaseSplitStatus := do
-  if (← isEqTrue e) then
-    if (← isEqTrue a <||> isEqTrue b) then
-      return .resolved
-    else
-      return .ready 2
-  else if (← isEqFalse e) then
-    return .resolved
-  else
-    return .notReady
-
-/--
-Given `e` of the form `a ∧ b`, check whether we are ready to case-split on `e`.
-That is, `e` is `False`, but neither `a` nor `b` is `False`.
- -/
-private def checkConjunctStatus (e a b : Expr) : GoalM CaseSplitStatus := do
-  if (← isEqTrue e) then
-    return .resolved
-  else if (← isEqFalse e) then
-    if (← isEqFalse a <||> isEqFalse b) then
-      return .resolved
-    else
-      return .ready 2
-  else
-    return .notReady
-
-/--
-Given `e` of the form `@Eq Prop a b`, check whether we are ready to case-split on `e`.
-There are two cases:
-1- `e` is `True`, but neither both `a` and `b` are `True`, nor both `a` and `b` are `False`.
-2- `e` is `False`, but neither `a` is `True` and `b` is `False`, nor `a` is `False` and `b` is `True`.
-/
-private def checkIffStatus (e a b : Expr) : GoalM CaseSplitStatus := do
-  if (← isEqTrue e) then
-    if (← (isEqTrue a <&&> isEqTrue b) <||> (isEqFalse a <&&> isEqFalse b)) then
-      return .resolved
-    else
-      return .ready 2
-  else if (← isEqFalse e) then
-    if (← (isEqTrue a <&&> isEqFalse b) <||> (isEqFalse a <&&> isEqTrue b)) then
-      return .resolved
-    else
-      return .ready 2
-  else
-    return .notReady
-
 private def checkCaseSplitStatus (e : Expr) : GoalM CaseSplitStatus := do
  match_expr e with
-  | Or a b => checkDisjunctStatus e a b
-  | And a b => checkConjunctStatus e a b
-  | Eq _ a b => checkIffStatus e a b
-  | ite _ c _ _ _ => checkIteCondStatus c
-  | dite _ c _ _ _ => checkIteCondStatus c
+  | Or a b =>
+    if (← isEqTrue e) then
+      if (← isEqTrue a <||> isEqTrue b) then
+        return .resolved
+      else
+        return .ready
+    else if (← isEqFalse e) then
+      return .resolved
+    else
+      return .notReady
+  | And a b =>
+    if (← isEqTrue e) then
+      return .resolved
+    else if (← isEqFalse e) then
+      if (← isEqFalse a <||> isEqFalse b) then
+        return .resolved
+      else
+        return .ready
+    else
+      return .notReady
+  | ite _ c _ _ _ =>
+    if (← isEqTrue c <||> isEqFalse c) then
+      return .resolved
+    else
+      return .ready
+  | dite _ c _ _ _ =>
+    if (← isEqTrue c <||> isEqFalse c) then
+      return .resolved
+    else
+      return .ready
  | _ =>
    if (← isResolvedCaseSplit e) then
      trace[grind.debug.split] "split resolved: {e}"
      return .resolved
-    if let some info := isMatcherAppCore? (← getEnv) e then
-      return .ready info.numAlts
+    if (← isMatcherApp e) then
+      return .ready
    let .const declName .. := e.getAppFn | unreachable!
-    if let some info ← isInductivePredicate? declName then
-      if (← isEqTrue e) then
-        return .ready info.ctors.length info.isRec
+    if (← isInductivePredicate declName <&&> isEqTrue e) then
+      return .ready
    return .notReady

-private inductive SplitCandidate where
-  | none
-  | some (c : Expr) (numCases : Nat) (isRec : Bool)
-
 /-- Returns the next case-split to be performed. It uses a very simple heuristic. -/
-private def selectNextSplit? : GoalM SplitCandidate := do
-  if (← isInconsistent) then return .none
-  if (← checkMaxCaseSplit) then return .none
-  go (← get).splitCandidates .none []
+private def selectNextSplit? : GoalM (Option Expr) := do
+  if (← isInconsistent) then return none
+  if (← checkMaxCaseSplit) then return none
+  go (← get).splitCandidates none []
 where
-  go (cs : List Expr) (c? : SplitCandidate) (cs' : List Expr) : GoalM SplitCandidate := do
+  go (cs : List Expr) (c? : Option Expr) (cs' : List Expr) : GoalM (Option Expr) := do
    match cs with
    | [] =>
      modify fun s => { s with splitCandidates := cs'.reverse }
-      if let .some _ numCases isRec := c? then
-        let numSplits := (← get).numSplits
-        -- We only increase the number of splits if there is more than one case or it is recursive.
-        let numSplits := if numCases > 1 || isRec then numSplits + 1 else numSplits
+      if c?.isSome then
        -- Remark: we reset `numEmatch` after each case split.
        -- We should consider other strategies in the future.
-        modify fun s => { s with numSplits, numEmatch := 0 }
+        modify fun s => { s with numSplits := s.numSplits + 1, numEmatch := 0 }
      return c?
    | c::cs =>
    match (← checkCaseSplitStatus c) with
    | .notReady => go cs c? (c::cs')
    | .resolved => go cs c? cs'
-    | .ready numCases isRec =>
+    | .ready =>
    match c? with
-    | .none => go cs (.some c numCases isRec) cs'
-    | .some c' numCases' _ =>
-     let isBetter : GoalM Bool := do
-       if numCases == 1 && !isRec && numCases' > 1 then
-         return true
-       if (← getGeneration c) < (← getGeneration c') then
-         return true
-       return numCases < numCases'
-     if (← isBetter) then
-        go cs (.some c numCases isRec) (c'::cs')
+    | none => go cs (some c) cs'
+    | some c' =>
+      if (← getGeneration c) < (← getGeneration c') then
+        go cs (some c) (c'::cs')
      else
        go cs c? (c::cs')

@@ -140,12 +94,7 @@ private def mkCasesMajor (c : Expr) : GoalM Expr := do
  | And a b => return mkApp3 (mkConst ``Grind.or_of_and_eq_false) a b (← mkEqFalseProof c)
  | ite _ c _ _ _ => return mkEM c
  | dite _ c _ _ _ => return mkEM c
-  | Eq _ a b =>
-    if (← isEqTrue c) then
-      return mkApp3 (mkConst ``Grind.of_eq_eq_true) a b (← mkEqTrueProof c)
-    else
-      return mkApp3 (mkConst ``Grind.of_eq_eq_false) a b (← mkEqFalseProof c)
-  | _ => return mkOfEqTrueCore c (← mkEqTrueProof c)
+  | _ => return mkApp2 (mkConst ``of_eq_true) c (← mkEqTrueProof c)

 /-- Introduces new hypotheses in each goal. -/
 private def introNewHyp (goals : List Goal) (acc : List Goal) (generation : Nat) : GrindM (List Goal) := do
@@ -159,10 +108,9 @@ and returns a new list of goals if successful.
 -/
 def splitNext : GrindTactic := fun goal => do
  let (goals?, _) ← GoalM.run goal do
-    let .some c numCases isRec ← selectNextSplit?
+    let some c ← selectNextSplit?
      | return none
    let gen ← getGeneration c
-    let genNew := if numCases > 1 || isRec then gen+1 else gen
    trace_goal[grind.split] "{c}, generation: {gen}"
    let mvarIds ← if (← isMatcherApp c) then
      casesMatch (← get).mvarId c
@@ -171,7 +119,7 @@ def splitNext : GrindTactic := fun goal => do
      cases (← get).mvarId major
    let goal ← get
    let goals := mvarIds.map fun mvarId => { goal with mvarId }
-    let goals ← introNewHyp goals [] genNew
+    let goals ← introNewHyp goals [] (gen+1)
    return some goals
  return goals?

--- a/src/Lean/Meta/Tactic/Grind/Types.lean
+++ b/src/Lean/Meta/Tactic/Grind/Types.lean
@@ -13,14 +13,17 @@ import Lean.Meta.CongrTheorems
 import Lean.Meta.AbstractNestedProofs
 import Lean.Meta.Tactic.Simp.Types
 import Lean.Meta.Tactic.Util
-import Lean.Meta.Tactic.Grind.ENodeKey
 import Lean.Meta.Tactic.Grind.Canon
 import Lean.Meta.Tactic.Grind.Attr
-import Lean.Meta.Tactic.Grind.Arith.Types
 import Lean.Meta.Tactic.Grind.EMatchTheorem

 namespace Lean.Meta.Grind

+@[inline] def isSameExpr (a b : Expr) : Bool :=
+  -- It is safe to use pointer equality because we hashcons all expressions
+  -- inserted into the E-graph
+  unsafe ptrEq a b
+
 /-- We use this auxiliary constant to mark delayed congruence proofs. -/
 def congrPlaceholderProof := mkConst (Name.mkSimple "[congruence]")

@@ -80,7 +83,6 @@ structure State where
  simpStats  : Simp.Stats := {}
  trueExpr   : Expr
  falseExpr  : Expr
-  natZExpr   : Expr
  /--
  Used to generate trace messages of the for `[grind] working on <tag>`,
  and implement the macro `trace_goal`.
@@ -105,10 +107,6 @@ def getTrueExpr : GrindM Expr := do
 def getFalseExpr : GrindM Expr := do
  return (← get).falseExpr

-/-- Returns the internalized `0 : Nat` numeral.  -/
-def getNatZeroExpr : GrindM Expr := do
-  return (← get).natZExpr
-
 def getMainDeclName : GrindM Name :=
  return (← readThe Context).mainDeclName

@@ -133,9 +131,9 @@ Applies hash-consing to `e`. Recall that all expressions in a `grind` goal have
 been hash-consed. We perform this step before we internalize expressions.
 -/
 def shareCommon (e : Expr) : GrindM Expr := do
-  modifyGet fun { canon, scState, nextThmIdx, congrThms, trueExpr, falseExpr, natZExpr, simpStats, lastTag } =>
+  modifyGet fun { canon, scState, nextThmIdx, congrThms, trueExpr, falseExpr, simpStats, lastTag } =>
    let (e, scState) := ShareCommon.State.shareCommon scState e
-    (e, { canon, scState, nextThmIdx, congrThms, trueExpr, falseExpr, natZExpr, simpStats, lastTag })
+    (e, { canon, scState, nextThmIdx, congrThms, trueExpr, falseExpr, simpStats, lastTag })

 /--
 Canonicalizes nested types, type formers, and instances in `e`.
@@ -207,19 +205,13 @@ structure ENode where
  on heterogeneous equality.
  -/
  heqProofs : Bool := false
-  /-- Unique index used for pretty printing and debugging purposes. -/
+  /--
+  Unique index used for pretty printing and debugging purposes.
+  -/
  idx : Nat := 0
-  /-- The generation in which this enode was created. -/
  generation : Nat := 0
  /-- Modification time -/
  mt : Nat := 0
-  /--
-  The `offset?` field is used to propagate equalities from the `grind` congruence closure module
-  to the offset constraints module. When `grind` merges two equivalence classes, and both have
-  an associated `offset?` set to `some e`, the equality is propagated. This field is
-  assigned during the internalization of offset terms.
-  -/
-  offset? : Option Expr := none
  deriving Inhabited, Repr

 def ENode.isCongrRoot (n : ENode) :=
@@ -232,6 +224,20 @@ structure NewEq where
  proof : Expr
  isHEq : Bool

+/--
+Key for the `ENodeMap` and `ParentMap` map.
+We use pointer addresses and rely on the fact all internalized expressions
+have been hash-consed, i.e., we have applied `shareCommon`.
+-/
+private structure ENodeKey where
+  expr : Expr
+
+instance : Hashable ENodeKey where
+  hash k := unsafe (ptrAddrUnsafe k.expr).toUInt64
+
+instance : BEq ENodeKey where
+  beq k₁ k₂ := isSameExpr k₁.expr k₂.expr
+
 abbrev ENodeMap := PHashMap ENodeKey ENode

 /--
@@ -362,8 +368,6 @@ structure Goal where
  gmt          : Nat := 0
  /-- Next unique index for creating ENodes -/
  nextIdx      : Nat := 0
-  /-- State of arithmetic procedures -/
-  arith        : Arith.State := {}
  /-- Active theorems that we have performed ematching at least once. -/
  thms         : PArray EMatchTheorem := {}
  /-- Active theorems that we have not performed any round of ematching yet. -/
@@ -389,10 +393,6 @@ structure Goal where
  numSplits : Nat := 0
  /-- Case-splits that do not have to be performed anymore. -/
  resolvedSplits : PHashSet ENodeKey := {}
-  /-- Next local E-match theorem idx. -/
-  nextThmIdx : Nat := 0
-  /-- Asserted facts -/
-  facts      : PArray Expr := {}
  deriving Inhabited

 def Goal.admit (goal : Goal) : MetaM Unit :=
@@ -461,25 +461,14 @@ def checkMaxEmatchExceeded : GoalM Bool := do
 Returns `some n` if `e` has already been "internalized" into the
 Otherwise, returns `none`s.
 -/
-def Goal.getENode? (goal : Goal) (e : Expr) : Option ENode :=
-  goal.enodes.find? { expr := e }
-
-@[inline, inherit_doc Goal.getENode?]
 def getENode? (e : Expr) : GoalM (Option ENode) :=
-  return (← get).getENode? e
-
-def throwNonInternalizedExpr (e : Expr) : CoreM α :=
-  throwError "internal `grind` error, term has not been internalized{indentExpr e}"
+  return (← get).enodes.find? { expr := e }

 /-- Returns node associated with `e`. It assumes `e` has already been internalized. -/
-def Goal.getENode (goal : Goal) (e : Expr) : CoreM ENode := do
-  let some n := goal.enodes.find? { expr := e }
-    | throwNonInternalizedExpr e
-  return n
-
-@[inline, inherit_doc Goal.getENode]
 def getENode (e : Expr) : GoalM ENode := do
-  (← get).getENode e
+  let some n := (← get).enodes.find? { expr := e }
+    | throwError "internal `grind` error, term has not been internalized{indentExpr e}"
+  return n

 /-- Returns the generation of the given term. Is assumes it has been internalized -/
 def getGeneration (e : Expr) : GoalM Nat :=
@@ -510,53 +499,30 @@ def isRoot (e : Expr) : GoalM Bool := do
  return isSameExpr n.root e

 /-- Returns the root element in the equivalence class of `e` IF `e` has been internalized. -/
-def Goal.getRoot? (goal : Goal) (e : Expr) : Option Expr := Id.run do
-  let some n ← goal.getENode? e | return none
+def getRoot? (e : Expr) : GoalM (Option Expr) := do
+  let some n ← getENode? e | return none
  return some n.root

-@[inline, inherit_doc Goal.getRoot?]
-def getRoot? (e : Expr) : GoalM (Option Expr) := do
-  return (← get).getRoot? e
-
 /-- Returns the root element in the equivalence class of `e`. -/
-def Goal.getRoot (goal : Goal) (e : Expr) : CoreM Expr :=
-  return (← goal.getENode e).root
-
-@[inline, inherit_doc Goal.getRoot]
-def getRoot (e : Expr) : GoalM Expr := do
-  (← get).getRoot e
+def getRoot (e : Expr) : GoalM Expr :=
+  return (← getENode e).root

 /-- Returns the root enode in the equivalence class of `e`. -/
 def getRootENode (e : Expr) : GoalM ENode := do
  getENode (← getRoot e)

-/--
-Returns the next element in the equivalence class of `e`
-if `e` has been internalized in the given goal.
-/
-def Goal.getNext? (goal : Goal) (e : Expr) : Option Expr := Id.run do
-  let some n ← goal.getENode? e | return none
-  return some n.next
-
 /-- Returns the next element in the equivalence class of `e`. -/
-def Goal.getNext (goal : Goal) (e : Expr) : CoreM Expr :=
-  return (← goal.getENode e).next
-
-@[inline, inherit_doc Goal.getRoot]
-def getNext (e : Expr) : GoalM Expr := do
-  (← get).getNext e
+def getNext (e : Expr) : GoalM Expr :=
+  return (← getENode e).next

 /-- Returns `true` if `e` has already been internalized. -/
 def alreadyInternalized (e : Expr) : GoalM Bool :=
  return (← get).enodes.contains { expr := e }

-def Goal.getTarget? (goal : Goal) (e : Expr) : Option Expr := Id.run do
-  let some n ← goal.getENode? e | return none
+def getTarget? (e : Expr) : GoalM (Option Expr) := do
+  let some n ← getENode? e | return none
  return n.target?

-@[inline] def getTarget? (e : Expr) : GoalM (Option Expr) := do
-  return (← get).getTarget? e
-
 /--
 If `isHEq` is `false`, it pushes `lhs = rhs` with `proof` to `newEqs`.
 Otherwise, it pushes `HEq lhs rhs`.
@@ -654,41 +620,6 @@ def mkENode (e : Expr) (generation : Nat) : GoalM Unit := do
  let interpreted ← isInterpreted e
  mkENodeCore e interpreted ctor generation

-/--
-Notify the offset constraint module that `a = b` where
-`a` and `b` are terms that have been internalized by this module.
-/
-@[extern "lean_process_new_offset_eq"] -- forward definition
-opaque Arith.processNewOffsetEq (a b : Expr) : GoalM Unit
-
-/--
-Notify the offset constraint module that `a = k` where
-`a` is term that has been internalized by this module,
-and `k` is a numeral.
-/
-@[extern "lean_process_new_offset_eq_lit"] -- forward definition
-opaque Arith.processNewOffsetEqLit (a k : Expr) : GoalM Unit
-
-/-- Returns `true` if `e` is a numeral and has type `Nat`. -/
-def isNatNum (e : Expr) : Bool := Id.run do
-  let_expr OfNat.ofNat _ _ inst := e | false
-  let_expr instOfNatNat _ := inst | false
-  true
-
-/--
-Marks `e` as a term of interest to the offset constraint module.
-If the root of `e`s equivalence class has already a term of interest,
-a new equality is propagated to the offset module.
-/
-def markAsOffsetTerm (e : Expr) : GoalM Unit := do
-  let root ← getRootENode e
-  if let some e' := root.offset? then
-    Arith.processNewOffsetEq e e'
-  else if isNatNum root.self && !isSameExpr e root.self then
-    Arith.processNewOffsetEqLit e root.self
-  else
-    setENode root.self { root with offset? := some e }
-
 /-- Returns `true` is `e` is the root of its congruence class. -/
 def isCongrRoot (e : Expr) : GoalM Bool := do
  return (← getENode e).isCongrRoot
@@ -763,23 +694,11 @@ def closeGoal (falseProof : Expr) : GoalM Unit := do
    else
      mvarId.assign (← mkFalseElim target falseProof)

-def Goal.getENodes (goal : Goal) : Array ENode :=
-  -- We must sort because we are using pointer addresses as keys in `enodes`
-  let nodes := goal.enodes.toArray.map (·.2)
-  nodes.qsort fun a b => a.idx < b.idx
-
 /-- Returns all enodes in the goal -/
 def getENodes : GoalM (Array ENode) := do
-  return (← get).getENodes
-
-/-- Executes `f` to each term in the equivalence class containing `e` -/
-@[inline] def traverseEqc (e : Expr) (f : ENode → GoalM Unit) : GoalM Unit := do
-  let mut curr := e
-  repeat
-    let n ← getENode curr
-    f n
-    if isSameExpr n.next e then return ()
-    curr := n.next
+  -- We must sort because we are using pointer addresses as keys in `enodes`
+  let nodes := (← get).enodes.toArray.map (·.2)
+  return nodes.qsort fun a b => a.idx < b.idx

 def forEachENode (f : ENode → GoalM Unit) : GoalM Unit := do
  let nodes ← getENodes
@@ -793,7 +712,7 @@ def filterENodes (p : ENode → GoalM Bool) : GoalM (Array ENode) := do
      ref.modify (·.push n)
  ref.get

-def forEachEqcRoot (f : ENode → GoalM Unit) : GoalM Unit := do
+def forEachEqc (f : ENode → GoalM Unit) : GoalM Unit := do
  let nodes ← getENodes
  for n in nodes do
    if isSameExpr n.self n.root then
@@ -828,34 +747,26 @@ def applyFallback : GoalM Unit := do
  fallback

 /-- Returns expressions in the given expression equivalence class. -/
-partial def Goal.getEqc (goal : Goal) (e : Expr) : List Expr :=
+partial def getEqc (e : Expr) : GoalM (List Expr) :=
  go e e []
 where
-  go (first : Expr) (e : Expr) (acc : List Expr) : List Expr := Id.run do
-    let some next ← goal.getNext? e | acc
+  go (first : Expr) (e : Expr) (acc : List Expr) : GoalM (List Expr) := do
+    let next ← getNext e
    let acc := e :: acc
    if isSameExpr first next then
      return acc
    else
      go first next acc

-@[inline, inherit_doc Goal.getEqc]
-partial def getEqc (e : Expr) : GoalM (List Expr) :=
-  return (← get).getEqc e
-
 /-- Returns all equivalence classes in the current goal. -/
-partial def Goal.getEqcs (goal : Goal) : List (List Expr) := Id.run do
-  let mut r : List (List Expr) := []
-  let nodes ← goal.getENodes
+partial def getEqcs : GoalM (List (List Expr)) := do
+  let mut r := []
+  let nodes ← getENodes
  for node in nodes do
    if isSameExpr node.root node.self then
-      r := goal.getEqc node.self :: r
+      r := (← getEqc node.self) :: r
  return r

-@[inline, inherit_doc Goal.getEqcs]
-def getEqcs : GoalM (List (List Expr)) :=
-  return (← get).getEqcs
-
 /-- Returns `true` if `e` is a case-split that does not need to be performed anymore. -/
 def isResolvedCaseSplit (e : Expr) : GoalM Bool :=
  return (← get).resolvedSplits.contains { expr := e }
--- a/src/Lean/Meta/Tactic/LinearArith/Nat/Simp.lean
+++ b/src/Lean/Meta/Tactic/LinearArith/Nat/Simp.lean
@@ -50,24 +50,18 @@ def simpCnstr? (e : Expr) : MetaM (Option (Expr × Expr)) := do
  if let some arg := e.not? then
    let mut eNew?   := none
    let mut thmName := Name.anonymous
-    match_expr arg with
-    | LE.le α _ _ _ =>
-      if α.isConstOf ``Nat then
-        eNew?   := some (← mkLE (← mkAdd (arg.getArg! 3) (mkNatLit 1)) (arg.getArg! 2))
-        thmName := ``Nat.not_le_eq
-    | GE.ge α _ _ _ =>
-      if α.isConstOf ``Nat then
-        eNew?   := some (← mkLE (← mkAdd (arg.getArg! 2) (mkNatLit 1)) (arg.getArg! 3))
-        thmName := ``Nat.not_ge_eq
-    | LT.lt α _ _ _ =>
-      if α.isConstOf ``Nat then
-        eNew?   := some (← mkLE (arg.getArg! 3) (arg.getArg! 2))
-        thmName := ``Nat.not_lt_eq
-    | GT.gt α _ _ _ =>
-      if α.isConstOf ``Nat then
-        eNew?   := some (← mkLE (arg.getArg! 2) (arg.getArg! 3))
-        thmName := ``Nat.not_gt_eq
-    | _ => pure ()
+    if arg.isAppOfArity ``LE.le 4 then
+      eNew?   := some (← mkLE (← mkAdd (arg.getArg! 3) (mkNatLit 1)) (arg.getArg! 2))
+      thmName := ``Nat.not_le_eq
+    else if arg.isAppOfArity ``GE.ge 4 then
+      eNew?   := some (← mkLE (← mkAdd (arg.getArg! 2) (mkNatLit 1)) (arg.getArg! 3))
+      thmName := ``Nat.not_ge_eq
+    else if arg.isAppOfArity ``LT.lt 4 then
+      eNew?   := some (← mkLE (arg.getArg! 3) (arg.getArg! 2))
+      thmName := ``Nat.not_lt_eq
+    else if arg.isAppOfArity ``GT.gt 4 then
+      eNew?   := some (← mkLE (arg.getArg! 2) (arg.getArg! 3))
+      thmName := ``Nat.not_gt_eq
    if let some eNew := eNew? then
      let h₁ := mkApp2 (mkConst thmName) (arg.getArg! 2) (arg.getArg! 3)
      if let some (eNew', h₂) ← simpCnstrPos? eNew then
--- a/src/Lean/Parser/Basic.lean
+++ b/src/Lean/Parser/Basic.lean
@@ -1583,8 +1583,8 @@ namespace TokenMap

 def insert (map : TokenMap α) (k : Name) (v : α) : TokenMap α :=
  match map.find? k with
-  | none    => RBMap.insert map k [v]
-  | some vs => RBMap.insert map k (v::vs)
+  | none    => .insert map k [v]
+  | some vs => .insert map k (v::vs)

 instance : Inhabited (TokenMap α) where
  default := RBMap.empty
--- a/src/Lean/ParserCompiler.lean
+++ b/src/Lean/ParserCompiler.lean
@@ -103,8 +103,11 @@ partial def compileParserExpr (e : Expr) : MetaM Expr := do
          name := c', levelParams := []
          type := ty, value := value, hints := ReducibilityHints.opaque, safety := DefinitionSafety.safe
        }
-        addAndCompile decl
-        modifyEnv (ctx.combinatorAttr.setDeclFor · c c')
+        let env ← getEnv
+        let env ← match env.addAndCompile {} decl with
+          | Except.ok    env => pure env
+          | Except.error kex => do throwError (← (kex.toMessageData {}).toString)
+        setEnv <| ctx.combinatorAttr.setDeclFor env c c'
        if cinfo.type.isConst then
          if let some kind ← parserNodeKind? cinfo.value! then
            -- If the parser is parameter-less and produces a node of kind `kind`,
--- a/src/Lean/Server/Requests.lean
+++ b/src/Lean/Server/Requests.lean
@@ -97,7 +97,7 @@ abbrev RequestT m := ReaderT RequestContext <| ExceptT RequestError m
 /-- Workers execute request handlers in this monad. -/
 abbrev RequestM := ReaderT RequestContext <| EIO RequestError

-abbrev RequestTask.pure (a : α) : RequestTask α := Task.pure (.ok a)
+abbrev RequestTask.pure (a : α) : RequestTask α := .pure (.ok a)

 instance : MonadLift IO RequestM where
  monadLift x := do
--- a/src/Lean/Util/Path.lean
+++ b/src/Lean/Util/Path.lean
@@ -104,26 +104,17 @@ def initSearchPath (leanSysroot : FilePath) (sp : SearchPath := ∅) : IO Unit :
 private def initSearchPathInternal : IO Unit := do
  initSearchPath (← getBuildDir)

-/-- Find the compiled `.olean` of a module in the `LEAN_PATH` search path. -/
 partial def findOLean (mod : Name) : IO FilePath := do
  let sp ← searchPathRef.get
  if let some fname ← sp.findWithExt "olean" mod then
    return fname
  else
    let pkg := FilePath.mk <| mod.getRoot.toString (escape := false)
-    throw <| IO.userError s!"unknown module prefix '{pkg}'\n\n\
-      No directory '{pkg}' or file '{pkg}.olean' in the search path entries:\n\
-      {"\n".intercalate <| sp.map (·.toString)}"
+    let mut msg := s!"unknown module prefix '{pkg}'

-/-- Find the `.lean` source of a module in a `LEAN_SRC_PATH` search path. -/
-partial def findLean (sp : SearchPath) (mod : Name) : IO FilePath := do
-  if let some fname ← sp.findWithExt "lean" mod then
-    return fname
-  else
-    let pkg := FilePath.mk <| mod.getRoot.toString (escape := false)
-    throw <| IO.userError s!"unknown module prefix '{pkg}'\n\n\
-      No directory '{pkg}' or file '{pkg}.lean' in the search path entries:\n\
-      {"\n".intercalate <| sp.map (·.toString)}"
+No directory '{pkg}' or file '{pkg}.olean' in the search path entries:
+{"\n".intercalate <| sp.map (·.toString)}"
+    throw <| IO.userError msg

 /-- Infer module name of source file name. -/
@[export lean_module_name_of_file]
--- a/src/Lean/Widget/InteractiveDiagnostic.lean
+++ b/src/Lean/Widget/InteractiveDiagnostic.lean
@@ -207,9 +207,7 @@ partial def msgToInteractive (msgData : MessageData) (hasWidgets : Bool) (indent
        | .widget wi alt =>
          return .tag (.widget wi (← fmtToTT alt col)) default
        | .trace cls msg collapsed children => do
-          -- absolute column = request-level indentation (e.g. from nested lazy trace request) +
-          -- offset inside `fmt`
-          let col := indent + col
+          let col := col + tt.stripTags.length - 2
          let children ←
            match children with
              | .lazy children => pure <| .lazy ⟨{indent := col+2, children := children.map .mk}⟩
--- a/src/Std.lean
+++ b/src/Std.lean
@@ -10,4 +10,3 @@ import Std.Sync
 import Std.Time
 import Std.Tactic
 import Std.Internal
-import Std.Net
--- a/src/Std/Data/DHashMap/Basic.lean
+++ b/src/Std/Data/DHashMap/Basic.lean
@@ -251,27 +251,34 @@ instance [BEq α] [Hashable α] : ForIn m (DHashMap α β) ((a : α) × β a) wh
 Modifies in place the value associated with a given key.

 This function ensures that the value is used linearly.
+It is currently implemented in terms of `get?`, `erase`, and `insert`,
+but will later become a primitive operation.
+(It is provided already to help avoid non-linear code.)
 -/
@[inline] def modify [LawfulBEq α] (m : DHashMap α β) (a : α) (f : β a → β a) : DHashMap α β :=
-  ⟨Raw₀.modify ⟨m.1, m.2.size_buckets_pos⟩ a f, Raw.WF.modify₀ m.2⟩
-
-@[inline, inherit_doc DHashMap.modify] def Const.modify {β : Type v} (m : DHashMap α (fun _ => β))
-    (a : α) (f : β → β) : DHashMap α (fun _ => β) :=
-  ⟨Raw₀.Const.modify ⟨m.1, m.2.size_buckets_pos⟩ a f, Raw.WF.constModify₀ m.2⟩
+  match m.get? a with
+  | none => m
+  | some b => m.erase a |>.insert a (f b)

 /--
 Modifies in place the value associated with a given key,
 allowing creating new values and deleting values via an `Option` valued replacement function.

 This function ensures that the value is used linearly.
+It is currently implemented in terms of `get?`, `erase`, and `insert`,
+but will later become a primitive operation.
+(It is provided already to help avoid non-linear code.)
 -/
-@[inline] def alter [LawfulBEq α] (m : DHashMap α β)
-    (a : α) (f : Option (β a) → Option (β a)) : DHashMap α β :=
-  ⟨Raw₀.alter ⟨m.1, m.2.size_buckets_pos⟩ a f, Raw.WF.alter₀ m.2⟩
-
-@[inline, inherit_doc DHashMap.alter] def Const.alter {β : Type v}
-    (m : DHashMap α (fun _ => β)) (a : α) (f : Option β → Option β) : DHashMap α (fun _ => β) :=
-  ⟨Raw₀.Const.alter ⟨m.1, m.2.size_buckets_pos⟩ a f, Raw.WF.constAlter₀ m.2⟩
+@[inline] def alter [LawfulBEq α] (m : DHashMap α β) (a : α) (f : Option (β a) → Option (β a)) : DHashMap α β :=
+  match m.get? a with
+  | none =>
+    match f none with
+    | none => m
+    | some b => m.insert a b
+  | some b =>
+    match f (some b) with
+    | none => m.erase a
+    | some b => m.erase a |>.insert a b

@[inline, inherit_doc Raw.insertMany] def insertMany {ρ : Type w}
    [ForIn Id ρ ((a : α) × β a)] (m : DHashMap α β) (l : ρ) : DHashMap α β :=
--- a/src/Std/Data/DHashMap/Internal/AssocList/Basic.lean
+++ b/src/Std/Data/DHashMap/Internal/AssocList/Basic.lean
@@ -169,63 +169,6 @@ def erase [BEq α] (a : α) : AssocList α β → AssocList α β
  | nil => nil
  | cons k v l => bif k == a then l else cons k v (l.erase a)

-/-- Internal implementation detail of the hash map -/
-def modify [BEq α] [LawfulBEq α] (a : α) (f : β a → β a) :
-    AssocList α β → AssocList α β
-  | nil => nil
-  | cons k v l =>
-    if h : k == a then
-      have h' : k = a := eq_of_beq h
-      let b := f (cast (congrArg β h') v)
-      cons a b l
-    else
-      cons k v (modify a f l)
-
-/-- Internal implementation detail of the hash map -/
-def alter [BEq α] [LawfulBEq α] (a : α) (f : Option (β a) → Option (β a)) :
-    AssocList α β → AssocList α β
-  | nil => match f none with
-    | none => nil
-    | some b => cons a b nil
-  | cons k v l =>
-    if h : k == a then
-      have h' : k = a := eq_of_beq h
-      match f (some (cast (congrArg β h') v)) with
-      | none => l
-      | some b => cons a b l
-    else
-      let tail := alter a f l
-      cons k v tail
-
-namespace Const
-
-/-- Internal implementation detail of the hash map -/
-def modify [BEq α] {β : Type v} (a : α) (f : β → β) :
-    AssocList α (fun _ => β) → AssocList α (fun _ => β)
-  | nil => nil
-  | cons k v l =>
-    if k == a then
-      cons a (f v) l
-    else
-      cons k v (modify a f l)
-
-/-- Internal implementation detail of the hash map -/
-def alter [BEq α] {β : Type v} (a : α) (f : Option β → Option β) :
-    AssocList α (fun _ => β) → AssocList α (fun _ => β)
-  | nil => match f none with
-    | none => nil
-    | some b => AssocList.cons a b nil
-  | cons k v l =>
-    if k == a then
-      match f v with
-      | none => l
-      | some b => cons a b l
-    else
-      let tail := alter a f l
-      cons k v tail
-
-end Const
-
 /-- Internal implementation detail of the hash map -/
@[inline] def filterMap (f : (a : α) → β a → Option (γ a)) :
    AssocList α β → AssocList α γ :=
--- a/src/Std/Data/DHashMap/Internal/AssocList/Lemmas.lean
+++ b/src/Std/Data/DHashMap/Internal/AssocList/Lemmas.lean
@@ -199,45 +199,6 @@ theorem toList_filter {f : (a : α) → β a → Bool} {l : AssocList α β} :
    · exact (ih _).trans (by simpa using perm_middle.symm)
    · exact ih _

-theorem toList_alter [BEq α] [LawfulBEq α] {a : α} {f : Option (β a) → Option (β a)}
-    {l : AssocList α β} :
-    Perm (l.alter a f).toList (alterKey a f l.toList) := by
-  induction l
-  · simp only [alter, toList_nil, alterKey_nil]
-    split <;> simp_all
-  · rw [toList]
-    refine Perm.trans ?_ alterKey_cons_perm.symm
-    rw [alter]
-    split <;> (try split) <;> simp_all
-
-theorem modify_eq_alter [BEq α] [LawfulBEq α] {a : α} {f : β a → β a} {l : AssocList α β} :
-    modify a f l = alter a (·.map f) l := by
-  induction l
-  · rfl
-  · next ih => simp only [modify, beq_iff_eq, alter, Option.map_some', ih]
-
-namespace Const
-
-variable {β : Type v}
-
-theorem toList_alter [BEq α] [EquivBEq α] {a : α} {f : Option β → Option β}
-    {l : AssocList α (fun _ => β)} : Perm (alter a f l).toList (Const.alterKey a f l.toList) := by
-  induction l
-  · simp only [alter, toList_nil, alterKey_nil]
-    split <;> simp_all
-  · rw [toList]
-    refine Perm.trans ?_ Const.alterKey_cons_perm.symm
-    rw [alter]
-    split <;> (try split) <;> simp_all
-
-theorem modify_eq_alter [BEq α] [EquivBEq α] {a : α} {f : β → β} {l : AssocList α (fun _ => β)} :
-    modify a f l = alter a (·.map f) l := by
-  induction l
-  · rfl
-  · next ih => simp only [modify, beq_iff_eq, alter, Option.map_some', ih]
-
-end Const
-
 theorem foldl_apply {l : AssocList α β} {acc : List δ} (f : (a : α) → β a → δ) :
    l.foldl (fun acc k v => f k v :: acc) acc =
      (l.toList.map (fun p => f p.1 p.2)).reverse ++ acc := by
--- a/src/Std/Data/DHashMap/Internal/Defs.lean
+++ b/src/Std/Data/DHashMap/Internal/Defs.lean
@@ -226,72 +226,6 @@ where
    let buckets' := buckets.uset i (AssocList.cons a b bkt) h
    expandIfNecessary ⟨⟨size', buckets'⟩, by simpa [buckets']⟩

-/-- Internal implementation detail of the hash map -/
-@[inline] def modify [BEq α] [Hashable α] [LawfulBEq α] (m : Raw₀ α β) (a : α) (f : β a → β a) :
-    Raw₀ α β :=
-  let ⟨⟨size, buckets⟩, hm⟩ := m
-  let size' := size
-  let ⟨i, hi⟩ := mkIdx buckets.size hm (hash a)
-  let bucket := buckets[i]
-  if bucket.contains a then
-    let buckets := buckets.uset i .nil hi
-    let bucket := bucket.modify a f
-    ⟨⟨size, buckets.uset i bucket (by simpa [buckets])⟩, (by simpa [buckets])⟩
-  else
-    m
-
-/-- Internal implementation detail of the hash map -/
-@[inline] def Const.modify [BEq α] {β : Type v} [Hashable α] (m : Raw₀ α (fun _ => β)) (a : α)
-    (f : β → β) : Raw₀ α (fun _ => β) :=
-  let ⟨⟨size, buckets⟩, hm⟩ := m
-  let size' := size
-  let ⟨i, hi⟩ := mkIdx buckets.size hm (hash a)
-  let bucket := buckets[i]
-  if bucket.contains a then
-    let buckets := buckets.uset i .nil hi
-    let bucket := AssocList.Const.modify a f bucket
-    ⟨⟨size, buckets.uset i bucket (by simpa [buckets])⟩, (by simpa [buckets])⟩
-  else
-    m
-
-/-- Internal implementation detail of the hash map -/
-@[inline] def alter [BEq α] [Hashable α] [LawfulBEq α] (m : Raw₀ α β) (a : α)
-    (f : Option (β a) → Option (β a)) : Raw₀ α β :=
-  let ⟨⟨size, buckets⟩, hm⟩ := m
-  let ⟨i, h⟩ := mkIdx buckets.size hm (hash a)
-  let bkt := buckets[i]
-  if bkt.contains a then
-    let buckets' := buckets.uset i .nil h
-    let bkt' := bkt.alter a f
-    let size' := if bkt'.contains a then size else size - 1
-    ⟨⟨size', buckets'.uset i bkt' (by simpa [buckets'])⟩, by simpa [buckets']⟩
-  else
-    match f none with
-    | none => m
-    | some b =>
-      let size'    := size + 1
-      let buckets' := buckets.uset i (.cons a b bkt) h
-      expandIfNecessary ⟨⟨size', buckets'⟩, by simpa [buckets']⟩
-
-/-- Internal implementation detail of the hash map -/
-@[inline] def Const.alter [BEq α] [Hashable α] {β : Type v} (m : Raw₀ α (fun _ => β)) (a : α)
-    (f : Option β → Option β) : Raw₀ α (fun _ => β) :=
-  let ⟨⟨size, buckets⟩, hm⟩ := m
-  let ⟨i, h⟩ := mkIdx buckets.size hm (hash a)
-  let bkt := buckets[i]
-  if bkt.contains a then
-    let buckets' := buckets.uset i .nil h
-    let bkt' := AssocList.Const.alter a f bkt
-    let size' := if bkt'.contains a then size else size - 1
-    ⟨⟨size', buckets'.uset i bkt' (by simpa [buckets'])⟩, by simpa [buckets']⟩
-  else
-    match f none with
-    | none => m
-    | some b =>
-      let size'    := size + 1
-      let buckets' := buckets.uset i (.cons a b bkt) h
-      expandIfNecessary ⟨⟨size', buckets'⟩, by simpa [buckets']⟩
-
 /-- Internal implementation detail of the hash map -/
@[inline] def containsThenInsert [BEq α] [Hashable α] (m : Raw₀ α β) (a : α) (b : β a) :
    Bool × Raw₀ α β :=
--- a/src/Std/Data/DHashMap/Internal/List/Associative.lean
+++ b/src/Std/Data/DHashMap/Internal/List/Associative.lean
@@ -775,7 +775,6 @@ def eraseKey [BEq α] (k : α) : List ((a : α) × β a) → List ((a : α) ×
  | ⟨k', v'⟩ :: l => bif k' == k then l else ⟨k', v'⟩ :: eraseKey k l

@[simp] theorem eraseKey_nil [BEq α] {k : α} : eraseKey k ([] : List ((a : α) × β a)) = [] := rfl
-
 theorem eraseKey_cons [BEq α] {l : List ((a : α) × β a)} {k k' : α} {v' : β k'} :
    eraseKey k (⟨k', v'⟩ :: l) = bif k' == k then l else ⟨k', v'⟩ :: eraseKey k l := rfl

@@ -850,10 +849,10 @@ theorem isEmpty_eraseKey [BEq α] {l : List ((a : α) × β a)} {k : α} :
 theorem keys_eq_map (l : List ((a : α) × β a)) : keys l = l.map (·.1) := by
  induction l using assoc_induction <;> simp_all

-theorem length_keys_eq_length (l : List ((a : α) × β a)) : (keys l).length = l.length := by
+theorem length_keys_eq_length (l : List ((a : α) × β a)) : (keys l).length = l.length := by 
  induction l using assoc_induction <;> simp_all

-theorem isEmpty_keys_eq_isEmpty (l : List ((a : α) × β a)) : (keys l).isEmpty = l.isEmpty := by
+theorem isEmpty_keys_eq_isEmpty (l : List ((a : α) × β a)) : (keys l).isEmpty = l.isEmpty := by 
  induction l using assoc_induction <;> simp_all

 theorem containsKey_eq_keys_contains [BEq α] [PartialEquivBEq α] {l : List ((a : α) × β a)}
@@ -969,25 +968,8 @@ def insertEntry [BEq α]  (k : α) (v : β k) (l : List ((a : α) × β a)) : Li

@[simp]
 theorem insertEntry_nil [BEq α] {k : α} {v : β k} :
-    insertEntry k v ([] : List ((a : α) × β a)) = [⟨k, v⟩] :=
-  by simp [insertEntry]
-
-theorem insertEntry_cons_of_false [BEq α] {l : List ((a : α) × β a)} {k k' : α} {v : β k}
-    {v' : β k'} (h : (k' == k) = false) :
-    Perm (insertEntry k v (⟨k', v'⟩ :: l)) (⟨k', v'⟩ :: insertEntry k v l) := by
-  simp only [insertEntry, containsKey_cons, h, Bool.false_or, cond_eq_if]
-  split
-  · rw [replaceEntry_cons_of_false h]
-  · apply Perm.swap
-
-theorem insertEntry_cons_of_beq [BEq α] {l : List ((a : α) × β a)} {k k' : α} {v : β k} {v' : β k'}
-    (h : k' == k) : insertEntry k v (⟨k', v'⟩ :: l) = ⟨k, v⟩ :: l := by
-  simp_all only [insertEntry, containsKey_cons, Bool.true_or, cond_true, replaceEntry_cons_of_true]
-
-@[simp]
-theorem insertEntry_cons_self [BEq α] [ReflBEq α] {l : List ((a : α) × β a)} {k : α} {v : β k} :
-    insertEntry k v (⟨k, v⟩ :: l) = ⟨k, v⟩ :: l :=
-  insertEntry_cons_of_beq BEq.refl
+    insertEntry k v ([] : List ((a : α) × β a)) = [⟨k, v⟩] := by
+  simp [insertEntry]

 theorem insertEntry_of_containsKey [BEq α] {l : List ((a : α) × β a)} {k : α} {v : β k}
    (h : containsKey k l) : insertEntry k v l = replaceEntry k v l := by
@@ -1845,324 +1827,4 @@ theorem eraseKey_append_of_containsKey_right_eq_false [BEq α] {l l' : List ((a
    · rw [cond_false, cond_false, ih, List.cons_append]
    · rw [cond_true, cond_true]

-/-- Internal implementation detail of the hash map -/
-def alterKey [BEq α] [LawfulBEq α] (k : α) (f : Option (β k) → Option (β k))
-    (l : List ((a : α) × β a)) : List ((a : α) × β a) :=
-  match f (getValueCast? k l) with
-  | none => eraseKey k l
-  | some v => insertEntry k v l
-
-theorem length_alterKey [BEq α] [LawfulBEq α] {k : α} {f : Option (β k) → Option (β k)}
-    {l : List ((a : α) × β a)} : (alterKey k f l).length =
-    if h : containsKey k l then
-      if f (getValueCast k l h) |>.isSome then l.length else l.length - 1
-    else
-      if f none |>.isSome then l.length + 1 else l.length := by
-  rw [alterKey]
-  cases h : getValueCast? k l <;> split <;> simp_all [length_eraseKey, length_insertEntry,
-    containsKey_eq_isSome_getValueCast?, ← getValueCast?_eq_some_getValueCast]
-
-theorem alterKey_cons_perm [BEq α] [LawfulBEq α] {k : α} {f : Option (β k) → Option (β k)}
-    {k' : α} {v' : β k'} {l : List ((a : α) × β a)} :
-      Perm (alterKey k f (⟨k', v'⟩ :: l)) (if hk : k' == k then
-        match f (some (cast (congrArg β (eq_of_beq hk)) v')) with
-          | none => l
-          | some v => ⟨k, v⟩ :: l
-        else
-          ⟨k', v'⟩ :: alterKey k f l) := by
-  rw [alterKey]
-  by_cases hk' : k' == k
-  · simp only [hk', ↓reduceDIte]
-    rw [getValueCast?_cons_of_true hk', eraseKey_cons_of_beq hk']
-    simp [insertEntry_cons_of_beq hk']
-  · simp only [hk', Bool.false_eq_true, ↓reduceDIte]
-    rw [Bool.not_eq_true] at hk'
-    rw [getValueCast?_cons_of_false hk', eraseKey_cons_of_false hk', alterKey]
-    split
-    · rfl
-    · simp [insertEntry_cons_of_false hk']
-
-theorem alterKey_of_perm [BEq α] [LawfulBEq α] {a : α} {f : Option (β a) → Option (β a)}
-    {l l' : List ((a : α) × β a)} (hl : DistinctKeys l) (hp : Perm l l') :
-    Perm (alterKey a f l) (alterKey a f l') := by
-  simp only [alterKey, getValueCast?_of_perm hl hp]
-  split
-  · exact eraseKey_of_perm hl hp
-  · exact insertEntry_of_perm hl hp
-
-theorem alterKey_append_of_containsKey_right_eq_false [BEq α] [LawfulBEq α] {a : α}
-    {f : Option (β a) → Option (β a)} {l l' : List ((a : α) × β a)}
-    (hc : containsKey a l' = false) : alterKey a f (l ++ l') = alterKey a f l ++ l' := by
-  simp only [alterKey, getValueCast?_append_of_containsKey_eq_false hc,
-    eraseKey_append_of_containsKey_right_eq_false hc, insertEntry_append_of_not_contains_right hc]
-  split <;> rfl
-
-@[simp]
-theorem alterKey_nil [BEq α] [LawfulBEq α] {a : α} {f : Option (β a) → Option (β a)} :
-    alterKey a f [] = match f none with
-    | none => []
-    | some b => [⟨a, b⟩] := rfl
-
-theorem containsKey_alterKey_self [BEq α] [LawfulBEq α] {a : α} {f : Option (β a) → Option (β a)}
-    {l : List ((a : α) × β a)} (hl : DistinctKeys l) :
-    containsKey a (alterKey a f l) = (f (getValueCast? a l)).isSome := by
-  match l with
-  | [] =>
-    simp only [getValueCast?_nil, Bool.coe_iff_coe, alterKey_nil]
-    split <;> { rename_i heq; simp [heq] }
-  | x :: xs =>
-    simp only [alterKey, Bool.coe_iff_coe]
-    split
-    · next heq =>
-      simp only [hl, heq, Option.isSome_none, containsKey_eraseKey_self]
-    · next heq =>
-      simp only [containsKey_insertEntry, heq, beq_self_eq_true, Bool.true_or, Option.isSome_some]
-
-theorem DistinctKeys.alterKey [BEq α] [LawfulBEq α] {a : α} {f : Option (β a) → Option (β a)}
-    {l : List ((a : α) × β a)} (hl : DistinctKeys l) : DistinctKeys (alterKey a f l) := by
-  dsimp only [List.alterKey]
-  split
-  · exact DistinctKeys.eraseKey hl
-  · exact DistinctKeys.insertEntry hl
-
-/-- Internal implementation detail of the hash map -/
-def modifyKey [BEq α] [LawfulBEq α] (k : α) (f : β k → β k)
-    (l : List ((a : α) × β a)) : List ((a : α) × β a) :=
-  match getValueCast? k l with
-  | none => l
-  | some v => replaceEntry k (f v) l
-
-theorem modifyKey_eq_alterKey [BEq α] [LawfulBEq α] (k : α) (f : β k → β k)
-    (l : List ((a : α) × β a)) : modifyKey k f l = alterKey k (·.map f) l := by
-  rw [modifyKey, alterKey, Option.map.eq_def]
-  split <;> next h =>
-    simp [h, insertEntry, containsKey_eq_isSome_getValueCast?, eraseKey_of_containsKey_eq_false]
-
-theorem mem_replaceEntry_of_key_ne [BEq α] [LawfulBEq α] {a : α} {b : β a}
-    {l : List ((a : α) × β a)} (p : (a : α) × β a) (hne : p.1 ≠ a) :
-    p ∈ replaceEntry a b l ↔ p ∈ l := by
-  induction l
-  · simp only [replaceEntry_nil]
-  · next ih =>
-    simp only [replaceEntry, cond_eq_if]
-    split
-    · next h =>
-      simp only [beq_iff_eq] at h
-      simp only [List.mem_cons, Sigma.ext_iff, h]
-      apply Iff.intro <;> exact fun
-      | Or.inr y => Or.inr y
-      | Or.inl y => hne y.1 |> False.elim
-    · simp only [List.mem_cons, ih]
-
-theorem mem_insertEntry_of_key_ne [BEq α] [LawfulBEq α] {a : α} {b : β a}
-    {l : List ((a : α) × β a)} (p : (a : α) × β a)
-    (hne : p.1 ≠ a) : p ∈ insertEntry a b l ↔ p ∈ l := by
-  simp only [insertEntry, cond_eq_if]
-  split
-  · exact mem_replaceEntry_of_key_ne p hne
-  · simp only [List.mem_cons, or_iff_right_iff_imp, Sigma.ext_iff]
-    exact fun x => hne x.1 |> False.elim
-
-theorem mem_eraseKey_of_key_ne [BEq α] [LawfulBEq α] {a : α}
-    {l : List ((a : α) × β a)} (p : (a : α) × β a) (hne : p.1 ≠ a) : p ∈ eraseKey a l ↔ p ∈ l := by
-  induction l
-  · simp only [eraseKey_nil]
-  · next ih =>
-    simp only [eraseKey, List.mem_cons]
-    rw [cond_eq_if]
-    split
-    · next h =>
-      rw [iff_or_self, Sigma.ext_iff]
-      exact fun x => (beq_iff_eq.mp h ▸ hne) x.1 |> False.elim
-    · next h =>
-      simp only [List.mem_cons, ih]
-
-theorem mem_alterKey_of_key_ne [BEq α] [LawfulBEq α] {a : α} {f : Option (β a) → Option (β a)}
-    {l : List ((a : α) × β a)} (p : (a : α) × β a) (hne : p.1 ≠ a) :
-    p ∈ alterKey a f l ↔ p ∈ l := by
-  rw [alterKey]
-  split <;> simp only [mem_eraseKey_of_key_ne p hne, mem_insertEntry_of_key_ne p hne]
-
-theorem length_modifyKey [BEq α] [LawfulBEq α] (k : α) (f : β k → β k)
-    (l : List ((a : α) × β a)) : (modifyKey k f l).length = l.length := by
-  induction l
-  · rfl
-  · next ih =>
-    simp only [modifyKey]
-    split <;> next h => simp only [length_replaceEntry, List.length_cons]
-
-theorem containsKey_modifyKey_self [BEq α] [LawfulBEq α] (k : α) (f : β k → β k)
-    (l : List ((a : α) × β a)) : containsKey k (modifyKey k f l) = containsKey k l := by
-  induction l
-  · simp only [modifyKey, getValueCast?_nil, eraseKey_nil, containsKey_nil, Bool.false_eq_true]
-  · simp only [modifyKey, Bool.coe_iff_coe]
-    split
-    · rfl
-    · rw [containsKey_replaceEntry]
-
-namespace Const
-
-variable {β : Type v}
-
-/-- Internal implementation detail of the hash map -/
-def alterKey [BEq α] (k : α) (f : Option β → Option β)
-    (l : List ((_ : α) × β)) : List ((_ : α) × β) :=
-  match f (getValue? k l) with
-  | none => eraseKey k l
-  | some v => insertEntry k v l
-
-theorem length_alterKey [BEq α] [EquivBEq α] {k : α} {f : Option β → Option β}
-    {l : List ((_ : α) × β)} : (alterKey k f l).length =
-      if h : containsKey k l then
-        if f (some (getValue k l h)) |>.isSome then l.length else l.length - 1
-      else
-        if f none |>.isSome then l.length + 1 else l.length := by
-  rw [alterKey]
-  cases h : getValue? k l <;> split <;> simp_all [length_eraseKey, length_insertEntry,
-    containsKey_eq_isSome_getValue?, ← getValue?_eq_some_getValue, -getValue?_eq_none]
-
-theorem alterKey_cons_perm [BEq α] [EquivBEq α] {k : α} {f : Option β → Option β}
-    {k' : α} {v' : β} {l : List ((_ : α) × β)} :
-      Perm (alterKey k f (⟨k', v'⟩ :: l)) (if k' == k then
-        match f (some v') with
-          | none => l
-          | some v => ⟨k, v⟩ :: l
-        else
-          ⟨k', v'⟩ :: alterKey k f l) := by
-  rw [alterKey]
-  by_cases hk' : k' == k
-  · simp only [hk', ↓reduceDIte]
-    rw [getValue?_cons_of_true hk', eraseKey_cons_of_beq hk']
-    simp [insertEntry_cons_of_beq hk']
-  · simp only [hk', Bool.false_eq_true, ↓reduceDIte]
-    rw [Bool.not_eq_true] at hk'
-    rw [getValue?_cons_of_false hk', eraseKey_cons_of_false hk', alterKey]
-    split
-    · rfl
-    · simp [insertEntry_cons_of_false hk']
-
-theorem alterKey_of_perm [BEq α] [EquivBEq α] {a : α} {f : Option β → Option β}
-    {l l' : List ((_ : α) × β)} (hl : DistinctKeys l) (hp : Perm l l') :
-    Perm (alterKey a f l) (alterKey a f l') := by
-  simp only [alterKey, getValue?_of_perm hl hp]
-  split
-  · exact eraseKey_of_perm hl hp
-  · exact insertEntry_of_perm hl hp
-
-theorem alterKey_append_of_containsKey_right_eq_false [BEq α] [EquivBEq α] {a : α}
-    {f : Option β → Option β} {l l' : List ((_ : α) × β)}
-    (hc : containsKey a l' = false) : alterKey a f (l ++ l') = alterKey a f l ++ l' := by
-  simp only [alterKey, getValue?_append_of_containsKey_eq_false hc,
-    eraseKey_append_of_containsKey_right_eq_false hc, insertEntry_append_of_not_contains_right hc]
-  split <;> rfl
-
-@[simp]
-theorem alterKey_nil [BEq α] [EquivBEq α] {a : α} {f : Option β → Option β} :
-    alterKey a f [] = match f none with
-    | none => []
-    | some b => [⟨a, b⟩] := rfl
-
-theorem containsKey_alterKey_self [BEq α] [EquivBEq α] {a : α} {f : Option β → Option β}
-    {l : List ((_ : α) × β)} (hl : DistinctKeys l) :
-    containsKey a (alterKey a f l) ↔ (f (getValue? a l)).isSome := by
-  match l with
-  | [] =>
-    simp only [getValue?_nil, Bool.coe_iff_coe, alterKey_nil]
-    split <;> { rename_i heq; simp [heq] }
-  | x :: xs =>
-    simp only [alterKey, Bool.coe_iff_coe]
-    split
-    · next heq =>
-      simp only [hl, heq, Option.isSome_none, containsKey_eraseKey_self]
-    · next heq =>
-      simp only [containsKey_insertEntry, BEq.refl, Bool.true_or, heq, Option.isSome_some]
-
-theorem mem_replaceEntry_of_key_not_beq [BEq α] [EquivBEq α] {a : α} {b : β}
-    {l : List ((_ : α) × β)} (p : (_ : α) × β) (hne : (p.1 == a) = false) :
-    p ∈ replaceEntry a b l ↔ p ∈ l := by
-  induction l
-  · simp only [replaceEntry_nil]
-  · next ih =>
-    simp only [replaceEntry, cond_eq_if]
-    split
-    · next h =>
-      simp only [List.mem_cons, Sigma.ext_iff]
-      apply Iff.intro <;> exact fun
-      | Or.inr y => Or.inr y
-      | Or.inl y => by simp_all only [BEq.refl, Bool.true_eq_false]
-    · simp only [List.mem_cons, ih]
-
-theorem mem_insertEntry_of_key_ne [BEq α] [EquivBEq α] {a : α} {b : β}
-    {l : List ((_ : α) × β)} (p : (_ : α) × β)
-    (hne : (p.1 == a) = false) : p ∈ insertEntry a b l ↔ p ∈ l := by
-  simp only [insertEntry, cond_eq_if]
-  split
-  · exact mem_replaceEntry_of_key_not_beq p hne
-  · simp only [List.mem_cons, or_iff_right_iff_imp, Sigma.ext_iff]
-    rw [← Bool.not_eq_true] at hne
-    exact fun x => hne (beq_of_eq x.1) |> False.elim
-
-theorem mem_eraseKey_of_key_ne [BEq α] [EquivBEq α] {a : α}
-    {l : List ((_ : α) × β)} (p : (_ : α) × β) (hne : (p.1 == a) = false) :
-    p ∈ eraseKey a l ↔ p ∈ l := by
-  induction l
-  · simp only [eraseKey_nil]
-  · next ih =>
-    simp only [eraseKey, List.mem_cons]
-    rw [cond_eq_if]
-    split
-    · next h =>
-      rw [iff_or_self, Sigma.ext_iff]
-      intro ⟨h₁, h₂⟩
-      rw [h₁, h] at hne
-      contradiction
-    · next h =>
-      simp only [List.mem_cons, ih]
-
-theorem mem_alterKey_of_key_not_beq {β : Type v} [BEq α] [EquivBEq α] {a : α}
-    {f : Option β → Option β} {l : List ((_ : α) × β)} (p : (_ : α) × β)
-    (hne : (p.1 == a) = false) : p ∈ alterKey a f l ↔ p ∈ l := by
-  rw [alterKey]
-  split <;> simp only [mem_eraseKey_of_key_ne p hne, mem_insertEntry_of_key_ne p hne]
-
-/-- Internal implementation detail of the hash map -/
-def modifyKey [BEq α] [EquivBEq α] (k : α) (f : β → β)
-    (l : List ((_ : α) × β)) : List ((_ : α) × β) :=
-  match getValue? k l with
-  | none => l
-  | some v => replaceEntry k (f v) l
-
-theorem modifyKey_eq_alterKey [BEq α] [EquivBEq α] (k : α) (f : β → β)
-    (l : List ((_ : α) × β)) : modifyKey k f l = alterKey k (·.map f) l := by
-  rw [modifyKey, alterKey, Option.map.eq_def]
-  split <;> next h =>
-    simp [h, insertEntry, containsKey_eq_isSome_getValue?, eraseKey_of_containsKey_eq_false]
-
-theorem length_modifyKey [BEq α] [EquivBEq α] (k : α) (f : β → β)
-    (l : List ((_ : α) × β)) : (modifyKey k f l).length = l.length := by
-  induction l
-  · rfl
-  · next ih =>
-    simp only [modifyKey]
-    split <;> next h => simp only [length_replaceEntry, List.length_cons]
-
-theorem containsKey_modifyKey_self [BEq α] [EquivBEq α] (k : α) (f : β → β)
-    (l : List ((_ : α) × β)) : containsKey k (modifyKey k f l) = containsKey k l := by
-  induction l
-  · simp only [modifyKey, getValue?_nil, eraseKey_nil, containsKey_nil, Bool.false_eq_true]
-  · simp only [modifyKey, Bool.coe_iff_coe]
-    split
-    · rfl
-    · rw [containsKey_replaceEntry]
-
-end Const
-
-theorem DistinctKeys.constAlterKey {β : Type v} [BEq α] [EquivBEq α] {a : α}
-    {f : Option β → Option β} {l : List ((_ : α) × β)} (hl : DistinctKeys l) :
-    DistinctKeys (List.Const.alterKey a f l) := by
-  dsimp only [List.Const.alterKey]
-  split
-  · exact DistinctKeys.eraseKey hl
-  · exact DistinctKeys.insertEntry hl
-
 end List
--- a/src/Std/Data/DHashMap/Internal/Model.lean
+++ b/src/Std/Data/DHashMap/Internal/Model.lean
@@ -41,11 +41,6 @@ def bucket [Hashable α] (self : Array (AssocList α β)) (h : 0 < self.size) (k
  let ⟨i, h⟩ := mkIdx self.size h (hash k)
  self[i]

-theorem bucket_eq {α : Type u} {β : α → Type v} [Hashable α] (self : Array (AssocList α β))
-  (h : 0 < self.size) (k : α) : bucket self h k =
-    haveI := mkIdx self.size h (hash k) |>.2
-    self[mkIdx self.size h (hash k) |>.1] := rfl
-
 /-- Internal implementation detail of the hash map -/
 def updateBucket [Hashable α] (self : Array (AssocList α β)) (h : 0 < self.size) (k : α)
    (f : AssocList α β → AssocList α β) : Array (AssocList α β) :=
@@ -84,13 +79,6 @@ theorem size_withComputedSize {self : Array (AssocList α β)} :
 theorem buckets_withComputedSize {self : Array (AssocList α β)} :
    (withComputedSize self).buckets = self := rfl

-@[simp]
-theorem bucket_updateBucket [Hashable α] (self : Array (AssocList α β)) (h : 0 < self.size) (k : α)
-    (f : AssocList α β → AssocList α β) :
-    bucket (updateBucket self h k f) (by simpa using h) k = f (bucket self h k) := by
-  unfold bucket updateBucket mkIdx
-  simp
-
 theorem exists_bucket_of_uset [BEq α] [Hashable α]
  (self : Array (AssocList α β)) (i : USize) (hi : i.toNat < self.size) (d : AssocList α β) :
    ∃ l, Perm (toListModel self) (self[i.toNat].toList ++ l) ∧
@@ -177,14 +165,13 @@ theorem apply_bucket_with_proof {γ : α → Type w} [BEq α] [Hashable α] [Par
 /-- This is the general theorem to show that modification operations are correct. -/
 theorem toListModel_updateBucket [BEq α] [Hashable α] [PartialEquivBEq α] [LawfulHashable α]
    {m : Raw₀ α β} (hm : Raw.WFImp m.1) {a : α} {f : AssocList α β → AssocList α β}
-    {g : List ((a : α) × β a) → List ((a : α) × β a)} (hfg : ∀ {l}, Perm (f l).toList (g l.toList))
+    {g : List ((a : α) × β a) → List ((a : α) × β a)} (hfg : ∀ {l}, (f l).toList = g l.toList)
    (hg₁ : ∀ {l l'}, DistinctKeys l → Perm l l' → Perm (g l) (g l'))
    (hg₂ : ∀ {l l'}, containsKey a l' = false → g (l ++ l') = g l ++ l') :
    Perm (toListModel (updateBucket m.1.buckets m.2 a f)) (g (toListModel m.1.2)) := by
  obtain ⟨l, h₁, h₂, h₃⟩ := exists_bucket_of_update m.1.buckets m.2 a f
  refine h₂.trans (Perm.trans ?_ (hg₁ hm.distinct h₁).symm)
-  refine Perm.append_right l hfg |>.trans ?_
-  rw [hg₂]
+  rw [hfg, hg₂]
  exact h₃ hm.buckets_hash_self _ rfl

 /-- This is the general theorem to show that mapping operations (like `map` and `filter`) are
@@ -323,49 +310,6 @@ def eraseₘaux [BEq α] [Hashable α] (m : Raw₀ α β) (a : α) : Raw₀ α
 def eraseₘ [BEq α] [Hashable α] (m : Raw₀ α β) (a : α) : Raw₀ α β :=
  if m.containsₘ a then m.eraseₘaux a else m

-/-- Internal implementation detail of the hash map -/
-def alterₘ [BEq α] [Hashable α] [LawfulBEq α] (m : Raw₀ α β) (a : α)
-    (f : Option (β a) → Option (β a)) : Raw₀ α β :=
-  if h : m.containsₘ a then
-    let buckets' := updateBucket m.1.buckets m.2 a (fun l => l.alter a f)
-    let size' :=
-      if Raw₀.containsₘ ⟨withComputedSize buckets', by simpa [buckets'] using m.2⟩ a
-      then m.1.size else m.1.size - 1
-    ⟨⟨size', buckets'⟩, by simpa [buckets'] using m.2⟩
-  else
-    match f none with
-    | none => m
-    | some b => Raw₀.expandIfNecessary (m.consₘ a b)
-
-/-- Internal implementation detail of the hash map -/
-def modifyₘ [BEq α] [Hashable α] [LawfulBEq α] (m : Raw₀ α β) (a : α) (f : β a → β a) : Raw₀ α β :=
-  m.alterₘ a (·.map f)
-
-namespace Const
-
-variable {β : Type v}
-
-/-- Internal implementation detail of the hash map -/
-def alterₘ [BEq α] [Hashable α] (m : Raw₀ α (fun _ => β)) (a : α)
-    (f : Option β → Option β) : Raw₀ α (fun _ => β) :=
-  if h : m.containsₘ a then
-    let buckets' := updateBucket m.1.buckets m.2 a (fun l => AssocList.Const.alter a f l)
-    let size' :=
-      if Raw₀.containsₘ ⟨withComputedSize buckets', by simpa [buckets'] using m.2⟩ a
-      then m.1.size else m.1.size - 1
-    ⟨⟨size', buckets'⟩, by simpa [buckets'] using m.2⟩
-  else
-    match f none with
-    | none => m
-    | some b => Raw₀.expandIfNecessary (m.consₘ a b)
-
-/-- Internal implementation detail of the hash map -/
-def modifyₘ [BEq α] [Hashable α] (m : Raw₀ α (fun _ => β)) (a : α) (f : β → β) :
-    Raw₀ α (fun _ => β) :=
-  alterₘ m a (fun option => option.map f)
-
-end Const
-
 /-- Internal implementation detail of the hash map -/
 def filterMapₘ (m : Raw₀ α β) (f : (a : α) → β a → Option (δ a)) : Raw₀ α δ :=
  ⟨withComputedSize (updateAllBuckets m.1.buckets fun l => l.filterMap f), by simpa using m.2⟩
@@ -447,64 +391,6 @@ theorem insert_eq_insertₘ [BEq α] [Hashable α] (m : Raw₀ α β) (a : α) (
    simp only [Array.uset, Array.ugetElem_eq_getElem]
  · rfl

-theorem alter_eq_alterₘ [BEq α] [Hashable α] [LawfulBEq α] (m : Raw₀ α β) (a : α)
-    (f : Option (β a) → Option (β a)) : m.alter a f = m.alterₘ a f := by
-    dsimp only [alter, alterₘ, containsₘ, ← bucket_eq]
-    split
-    · congr 2
-      · simp only [withComputedSize, bucket_updateBucket]
-      · simp only [Array.uset, bucket, Array.ugetElem_eq_getElem, Array.set_set, updateBucket]
-    · congr
-
-theorem modify_eq_alter [BEq α] [Hashable α] [LawfulBEq α] (m : Raw₀ α β) (a : α)
-    (f : β a → β a) : m.modify a f = m.alter a (·.map f) := by
-  rw [modify, alter]
-  split
-  · dsimp
-    split
-    · next h =>
-      simp only [AssocList.contains_eq] at h
-      simp only [AssocList.modify_eq_alter, Array.set_set, AssocList.contains_eq,
-        containsKey_of_perm AssocList.toList_alter, ← modifyKey_eq_alterKey,
-        containsKey_modifyKey_self, h, ↓reduceIte]
-    · rfl
-
-theorem modify_eq_modifyₘ [BEq α] [Hashable α] [LawfulBEq α] (m : Raw₀ α β) (a : α)
-    (f : β a → β a) : m.modify a f = m.modifyₘ a f := by
-  rw [modify_eq_alter, alter_eq_alterₘ, modifyₘ]
-
-namespace Const
-
-variable {β : Type v}
-
-theorem alter_eq_alterₘ [BEq α] [Hashable α] [EquivBEq α] (m : Raw₀ α (fun _ => β)) (a : α)
-    (f : Option β → Option β) : Const.alter m a f = Const.alterₘ m a f := by
-    dsimp only [alter, alterₘ, containsₘ, ← bucket_eq]
-    split
-    · congr 2
-      · simp only [withComputedSize, bucket_updateBucket]
-      · simp only [Array.uset, bucket, Array.ugetElem_eq_getElem, Array.set_set, updateBucket]
-    · congr
-
-theorem modify_eq_alter [BEq α] [Hashable α] [EquivBEq α] (m : Raw₀ α (fun _ => β)) (a : α)
-    (f : β → β) : Const.modify m a f = Const.alter m a (·.map f) := by
-  rw [modify, alter]
-  split
-  · dsimp
-    split
-    · next h =>
-      simp only [AssocList.contains_eq] at h
-      simp only [AssocList.Const.modify_eq_alter, Array.set_set, AssocList.contains_eq,
-        containsKey_of_perm AssocList.Const.toList_alter, ← Const.modifyKey_eq_alterKey,
-        Const.containsKey_modifyKey_self, h, ↓reduceIte]
-    · rfl
-
-theorem modify_eq_modifyₘ [BEq α] [Hashable α] [EquivBEq α] (m : Raw₀ α (fun _ => β)) (a : α)
-    (f : β → β) : Const.modify m a f = Const.modifyₘ m a f := by
-  rw [modify_eq_alter, alter_eq_alterₘ, modifyₘ]
-
-end Const
-
 theorem containsThenInsert_eq_insertₘ [BEq α] [Hashable α] (m : Raw₀ α β) (a : α) (b : β a) :
    (m.containsThenInsert a b).2 = m.insertₘ a b := by
  rw [containsThenInsert, insertₘ, containsₘ, bucket]
--- a/src/Std/Data/DHashMap/Internal/WF.lean
+++ b/src/Std/Data/DHashMap/Internal/WF.lean
@@ -240,12 +240,6 @@ theorem toListModel_expandIfNecessary [BEq α] [Hashable α] [PartialEquivBEq α
  · dsimp
    exact toListModel_expand

-@[simp]
-theorem size_expandIfNecessary [BEq α] [Hashable α] {m : Raw₀ α β} :
-    (expandIfNecessary m).val.size = m.val.size := by
-  rw [expandIfNecessary]
-  split <;> rfl
-
 theorem wfImp_expandIfNecessary [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α] (m : Raw₀ α β)
    (h : Raw.WFImp m.1) : Raw.WFImp (expandIfNecessary m).1 := by
  rw [Raw₀.expandIfNecessary]
@@ -408,7 +402,7 @@ end
 theorem toListModel_replaceₘ [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α] (m : Raw₀ α β)
   (h : Raw.WFImp m.1) (a : α) (b : β a) :
  Perm (toListModel (m.replaceₘ a b).1.buckets) (replaceEntry a b (toListModel m.1.2)) :=
-  toListModel_updateBucket h (.of_eq AssocList.toList_replace) List.replaceEntry_of_perm
+  toListModel_updateBucket h AssocList.toList_replace List.replaceEntry_of_perm
    List.replaceEntry_append_of_containsKey_right_eq_false

 theorem isHashSelf_replaceₘ [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α] (m : Raw₀ α β)
@@ -428,7 +422,7 @@ theorem wfImp_replaceₘ [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α
 theorem toListModel_consₘ [BEq α] [Hashable α] [PartialEquivBEq α] [LawfulHashable α]
    (m : Raw₀ α β) (h : Raw.WFImp m.1) (a : α) (b : β a) :
    Perm (toListModel (m.consₘ a b).1.buckets) (⟨a, b⟩ :: (toListModel m.1.2)) :=
-  toListModel_updateBucket h .rfl (fun _ => Perm.cons _) (fun _ => cons_append _ _ _)
+  toListModel_updateBucket h rfl (fun _ => Perm.cons _) (fun _ => cons_append _ _ _)

 theorem isHashSelf_consₘ [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α] (m : Raw₀ α β)
    (h : Raw.WFImp m.1) (a : α) (b : β a) : IsHashSelf (m.consₘ a b).1.buckets := by
@@ -485,225 +479,6 @@ theorem wfImp_insert [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α] {m
  rw [insert_eq_insertₘ]
  exact wfImp_insertₘ h

-/-! # `alter` -/
-
-theorem toListModel_updateBucket_alter [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β}
-    (h : Raw.WFImp m.1) {a : α} {f : Option (β a) → Option (β a)} :
-    Perm (toListModel (updateBucket m.1.buckets m.2 a (AssocList.alter a f)))
-      (alterKey a f (toListModel m.1.buckets)) := by
-  exact toListModel_updateBucket h AssocList.toList_alter List.alterKey_of_perm
-    List.alterKey_append_of_containsKey_right_eq_false
-
-theorem isHashSelf_updateBucket_alter [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β}
-    (h : Raw.WFImp m.1) {a : α} {f : Option (β a) → Option (β a)} :
-    IsHashSelf (updateBucket m.1.buckets m.2 a (AssocList.alter a f)) := by
-  apply h.buckets_hash_self.updateBucket (fun l p hp => ?_)
-  rw [AssocList.toList_alter.mem_iff] at hp
-  by_cases h : p.fst = a
-  · exact .inr <| congrArg hash h
-  · rw [mem_alterKey_of_key_ne _ h] at hp
-    exact .inl <| containsKey_of_mem hp
-
-theorem wfImp_updateBucket_alter [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β}
-    (h : Raw.WFImp m.1) {a : α} {f : Option (β a) → Option (β a)} :
-    Raw.WFImp (withComputedSize <| updateBucket m.1.buckets m.2 a (AssocList.alter a f)) where
-  buckets_hash_self := isHashSelf_updateBucket_alter h
-  size_eq := by rw [size_withComputedSize, computeSize_eq, buckets_withComputedSize]
-  distinct := DistinctKeys.perm (toListModel_updateBucket_alter h) h.distinct.alterKey
-
-theorem isHashSelf_alterₘ [BEq α] [Hashable α] [LawfulBEq α] (m : Raw₀ α β) (h : Raw.WFImp m.1)
-    (a : α) (f : Option (β a) → Option (β a)) : IsHashSelf (m.alterₘ a f).1.buckets := by
-  dsimp only [alterₘ, withComputedSize]
-  split
-  · exact isHashSelf_updateBucket_alter h
-  · next hc =>
-    split
-    · exact h.buckets_hash_self
-    · refine (wfImp_expandIfNecessary _ (wfImp_consₘ _ h _ _ ?_)).buckets_hash_self
-      exact Bool.not_eq_true _ ▸ hc
-
-theorem toListModel_alterₘ [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β} (h : Raw.WFImp m.1)
-    {a : α} {f : Option (β a) → Option (β a)} :
-    Perm (toListModel (m.alterₘ a f).1.2) (alterKey a f (toListModel m.1.2)) := by
-  rw [alterₘ]
-  split
-  · exact toListModel_updateBucket_alter h
-  · next hc =>
-    rw [Bool.not_eq_true, containsₘ_eq_containsKey h] at hc
-    rw [alterKey, getValueCast?_eq_none hc]
-    split
-    · next hn =>
-      simp only [hn]
-      rw [eraseKey_of_containsKey_eq_false]
-      exact hc
-    · next hs =>
-      simp only [hs]
-      refine Perm.trans (toListModel_expandIfNecessary _) ?_
-      refine Perm.trans (toListModel_consₘ m h _ _) ?_
-      rw [insertEntry_of_containsKey_eq_false]
-      exact hc
-
-theorem toListModel_alter [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β} (h : Raw.WFImp m.1)
-    {a : α} {f : Option (β a) → Option (β a)} :
-    Perm (toListModel (m.alter a f).1.2) (alterKey a f (toListModel m.1.2)) := by
-  rw [alter_eq_alterₘ]
-  exact toListModel_alterₘ h
-
-theorem wfImp_alterₘ [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β} (h : Raw.WFImp m.1) {a : α}
-    {f : Option (β a) → Option (β a)} : Raw.WFImp (m.alterₘ a f).1 where
-  buckets_hash_self := isHashSelf_alterₘ m h a f
-  distinct := DistinctKeys.perm (toListModel_alterₘ h) h.distinct.alterKey
-  size_eq := by
-    rw [← Perm.length_eq (toListModel_alterₘ h).symm, alterₘ]
-    split
-    · next h₁ =>
-      rw [containsₘ_eq_containsKey h] at h₁
-      simp only [length_alterKey, h.size_eq, dif_pos h₁]
-      rw [containsₘ_eq_containsKey (by apply wfImp_updateBucket_alter h)]
-      simp only [buckets_withComputedSize]
-      simp only [containsKey_of_perm <| toListModel_updateBucket_alter h]
-      rw [← getValueCast?_eq_some_getValueCast h₁]
-      conv => lhs; congr; rw [containsKey_alterKey_self h.distinct]
-    · next h₁ =>
-      rw [containsₘ_eq_containsKey h] at h₁
-      rw [alterKey]
-      rw [getValueCast?_eq_none <| Bool.not_eq_true _ ▸ h₁]
-      split
-      · next heq =>
-        rw [heq, h.size_eq, length_eraseKey, if_neg h₁]
-      · next heq =>
-        rw [heq, size_expandIfNecessary, consₘ, length_insertEntry, if_neg h₁, h.size_eq]
-
-theorem wfImp_alter [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β}
-    (h : Raw.WFImp m.1) {a : α} {f : Option (β a) → Option (β a)} : Raw.WFImp (m.alter a f).1 := by
-  rw [alter_eq_alterₘ]
-  exact wfImp_alterₘ h
-
-namespace Const
-
-variable {β : Type v}
-
-theorem toListModel_updateBucket_alter [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α]
-    {m : Raw₀ α (fun _ => β)} (h : Raw.WFImp m.1) {a : α} {f : Option β → Option β} :
-    Perm (toListModel (updateBucket m.1.buckets m.2 a (AssocList.Const.alter a f)))
-      (Const.alterKey a f (toListModel m.1.buckets)) := by
-  exact toListModel_updateBucket h AssocList.Const.toList_alter List.Const.alterKey_of_perm
-    List.Const.alterKey_append_of_containsKey_right_eq_false
-
-theorem isHashSelf_updateBucket_alter [BEq α] [EquivBEq α] [Hashable α] [LawfulHashable α]
-    {m : Raw₀ α (fun _ => β)} (h : Raw.WFImp m.1) {a : α} {f : Option β → Option β} :
-    IsHashSelf (updateBucket m.1.buckets m.2 a (AssocList.Const.alter a f)) := by
-  apply h.buckets_hash_self.updateBucket (fun l p hp => ?_)
-  rw [AssocList.Const.toList_alter.mem_iff] at hp
-  by_cases h : p.fst == a
-  · exact .inr <| hash_eq h
-  · rw [Bool.not_eq_true] at h
-    rw [Const.mem_alterKey_of_key_not_beq _ h] at hp
-    exact .inl <| containsKey_of_mem hp
-
-theorem wfImp_updateBucket_alter [BEq α] [EquivBEq α] [Hashable α] [LawfulHashable α]
-    {m : Raw₀ α (fun _ => β)} (h : Raw.WFImp m.1) {a : α} {f : Option β → Option β} :
-    Raw.WFImp (withComputedSize <| updateBucket m.1.buckets m.2 a (AssocList.Const.alter a f)) where
-  buckets_hash_self := isHashSelf_updateBucket_alter h
-  size_eq := by rw [size_withComputedSize, computeSize_eq]; rfl
-  distinct := DistinctKeys.perm (toListModel_updateBucket_alter h) h.distinct.constAlterKey
-
-theorem isHashSelf_alterₘ [BEq α] [EquivBEq α] [Hashable α] [LawfulHashable α]
-    (m : Raw₀ α (fun _ => β)) (h : Raw.WFImp m.1) (a : α) (f : Option β → Option β) :
-  IsHashSelf (Const.alterₘ m a f).1.buckets := by
-  dsimp only [alterₘ, withComputedSize]
-  split
-  · exact isHashSelf_updateBucket_alter h
-  · next hc =>
-    split
-    · exact h.buckets_hash_self
-    · refine (wfImp_expandIfNecessary _ (wfImp_consₘ _ h _ _ ?_)).buckets_hash_self
-      exact Bool.not_eq_true _ ▸ hc
-
-theorem toListModel_alterₘ [BEq α] [EquivBEq α] [Hashable α] [LawfulHashable α]
-    {m : Raw₀ α (fun _ => β)} (h : Raw.WFImp m.1) {a : α} {f : Option β → Option β} :
-    Perm (toListModel (Const.alterₘ m a f).1.2) (Const.alterKey a f (toListModel m.1.2)) := by
-  rw [Const.alterₘ]
-  split
-  · exact toListModel_updateBucket_alter h
-  · next hc =>
-    rw [Bool.not_eq_true, containsₘ_eq_containsKey h] at hc
-    rw [Const.alterKey, getValue?_eq_none.mpr hc]
-    split
-    · next hn =>
-      simp only [hn]
-      rw [eraseKey_of_containsKey_eq_false]
-      exact hc
-    · next hs =>
-      simp only [hs]
-      refine Perm.trans (toListModel_expandIfNecessary _) ?_
-      refine Perm.trans (toListModel_consₘ m h _ _) ?_
-      rw [insertEntry_of_containsKey_eq_false]
-      exact hc
-
-theorem wfImp_alterₘ [BEq α] [EquivBEq α] [Hashable α] [LawfulHashable α] {m : Raw₀ α (fun _ => β)}
-    (h : Raw.WFImp m.1) {a : α} {f : Option β → Option β} : Raw.WFImp (Const.alterₘ m a f).1 where
-  buckets_hash_self := isHashSelf_alterₘ m h a f
-  distinct := DistinctKeys.perm (toListModel_alterₘ h) h.distinct.constAlterKey
-  size_eq := by
-    rw [← Perm.length_eq (toListModel_alterₘ h).symm, alterₘ]
-    split
-    · next h₁ =>
-      rw [containsₘ_eq_containsKey h] at h₁
-      simp only [Const.length_alterKey, h.size_eq, dif_pos h₁]
-      rw [containsₘ_eq_containsKey (by apply wfImp_updateBucket_alter h)]
-      simp only [buckets_withComputedSize]
-      simp only [containsKey_of_perm <| toListModel_updateBucket_alter h]
-      rw [← getValue?_eq_some_getValue h₁]
-      conv => lhs; congr; rw [Const.containsKey_alterKey_self h.distinct]
-    · next h₁ =>
-      rw [containsₘ_eq_containsKey h] at h₁
-      rw [Const.alterKey]
-      rw [getValue?_eq_none.mpr <| Bool.not_eq_true _ ▸ h₁]
-      split
-      · next heq =>
-        rw [heq, h.size_eq, length_eraseKey, if_neg h₁]
-      · next heq =>
-        rw [heq, size_expandIfNecessary, consₘ, length_insertEntry, if_neg h₁, h.size_eq]
-
-theorem wfImp_alter [BEq α] [EquivBEq α] [Hashable α] [LawfulHashable α] {m : Raw₀ α (fun _ => β)}
-    (h : Raw.WFImp m.1) {a : α} {f : Option β → Option β} : Raw.WFImp (Const.alter m a f).1 := by
-  rw [Const.alter_eq_alterₘ]
-  exact wfImp_alterₘ h
-
-end Const
-
-/-! # `modify` -/
-
-theorem toListModel_modify [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β} (h : Raw.WFImp m.1)
-    {a : α} {f : β a → β a} :
-    Perm (toListModel (m.modify a f).1.2) (modifyKey a f (toListModel m.1.2)) := by
-  rw [modify_eq_alter, modifyKey_eq_alterKey]
-  exact toListModel_alter h
-
-theorem wfImp_modifyₘ [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β}
-    (h : Raw.WFImp m.1) {a : α} {f : β a → β a} : Raw.WFImp (m.modifyₘ a f).1 := wfImp_alterₘ h
-
-theorem wfImp_modify [BEq α] [Hashable α] [LawfulBEq α] {m : Raw₀ α β} (h : Raw.WFImp m.1) {a : α}
-    {f : β a → β a} : Raw.WFImp (m.modify a f).1 := by
-  rw [modify_eq_modifyₘ]
-  exact wfImp_alterₘ h
-
-namespace Const
-
-variable {β : Type v}
-
-theorem wfImp_modifyₘ [BEq α] [EquivBEq α] [Hashable α] [LawfulHashable α] {m : Raw₀ α (fun _ => β)}
-    (h : Raw.WFImp m.1) {a : α} {f : β → β} : Raw.WFImp (Const.modifyₘ m a f).1 :=
-  Const.wfImp_alterₘ h
-
-theorem wfImp_modify [BEq α] [EquivBEq α] [Hashable α] [LawfulHashable α] {m : Raw₀ α (fun _ => β)}
-    (h : Raw.WFImp m.1) {a : α} {f : β → β} : Raw.WFImp (Const.modify m a f).1 := by
-  rw [Const.modify_eq_modifyₘ]
-  exact wfImp_alterₘ h
-
-end Const
-
 /-! # `containsThenInsert` -/

 theorem toListModel_containsThenInsert [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α]
@@ -799,7 +574,7 @@ theorem Const.wfImp_getThenInsertIfNew? {β : Type v} [BEq α] [Hashable α] [Eq
 theorem toListModel_eraseₘaux [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α] (m : Raw₀ α β)
    (a : α) (h : Raw.WFImp m.1) :
    Perm (toListModel (m.eraseₘaux a).1.buckets) (eraseKey a (toListModel m.1.buckets)) :=
-  toListModel_updateBucket h (.of_eq AssocList.toList_erase) List.eraseKey_of_perm
+  toListModel_updateBucket h AssocList.toList_erase List.eraseKey_of_perm
    List.eraseKey_append_of_containsKey_right_eq_false

 theorem isHashSelf_eraseₘaux [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α] (m : Raw₀ α β)
@@ -972,10 +747,6 @@ theorem WF.out [BEq α] [Hashable α] [i₁ : EquivBEq α] [i₂ : LawfulHashabl
  · next h => exact Raw₀.wfImp_getThenInsertIfNew? (by apply h)
  · next h => exact Raw₀.wfImp_filter (by apply h)
  · next h => exact Raw₀.Const.wfImp_getThenInsertIfNew? (by apply h)
-  · next h => exact Raw₀.wfImp_modify (by apply h)
-  · next h => exact Raw₀.Const.wfImp_modify (by apply h)
-  · next h => exact Raw₀.wfImp_alter (by apply h)
-  · next h => exact Raw₀.Const.wfImp_alter (by apply h)

 end Raw

@@ -991,8 +762,8 @@ theorem Const.wfImp_insertMany {β : Type v} [BEq α] [Hashable α] [EquivBEq α
    {l : ρ} (h : Raw.WFImp m.1) : Raw.WFImp (Const.insertMany m l).1.1 :=
  Raw.WF.out ((Const.insertMany m l).2 _ Raw.WF.insert₀ (.wf m.2 h))

-theorem Const.wfImp_insertManyIfNewUnit [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α]
-    {ρ : Type w} [ForIn Id ρ α] {m : Raw₀ α (fun _ => Unit)} {l : ρ} (h : Raw.WFImp m.1) :
+theorem Const.wfImp_insertManyIfNewUnit [BEq α] [Hashable α] [EquivBEq α] [LawfulHashable α] {ρ : Type w}
+    [ForIn Id ρ α] {m : Raw₀ α (fun _ => Unit)} {l : ρ} (h : Raw.WFImp m.1) :
    Raw.WFImp (Const.insertManyIfNewUnit m l).1.1 :=
  Raw.WF.out ((Const.insertManyIfNewUnit m l).2 _ Raw.WF.insertIfNew₀ (.wf m.2 h))

--- a/src/Std/Data/DHashMap/Raw.lean
+++ b/src/Std/Data/DHashMap/Raw.lean
@@ -509,18 +509,6 @@ inductive WF : {α : Type u} → {β : α → Type v} → [BEq α] → [Hashable
  /-- Internal implementation detail of the hash map -/
  | constGetThenInsertIfNew?₀ {α β} [BEq α] [Hashable α] {m : Raw α (fun _ => β)} {h a b} :
      WF m → WF (Raw₀.Const.getThenInsertIfNew? ⟨m, h⟩ a b).2.1
-  /-- Internal implementation detail of the hash map -/
-  | modify₀ {α β} [BEq α] [Hashable α] [LawfulBEq α] {m : Raw α β} {h a} {f : β a → β a} :
-      WF m → WF (Raw₀.modify ⟨m, h⟩ a f).1
-  /-- Internal implementation detail of the hash map -/
-  | constModify₀ {α} {β : Type v} [BEq α] [Hashable α] {m : Raw α (fun _ => β)} {h a} {f : β → β} :
-      WF m → WF (Raw₀.Const.modify ⟨m, h⟩ a f).1
-  /-- Internal implementation detail of the hash map -/
-  | alter₀ {α β} [BEq α] [Hashable α] [LawfulBEq α] {m : Raw α β} {h a}
-      {f : Option (β a) → Option (β a)} : WF m → WF (Raw₀.alter ⟨m, h⟩ a f).1
-  /-- Internal implementation detail of the hash map -/
-  | constAlter₀ {α} {β : Type v} [BEq α] [Hashable α] {m : Raw α (fun _ => β)} {h a}
-      {f : Option β → Option β} : WF m → WF (Raw₀.Const.alter ⟨m, h⟩ a f).1

 /-- Internal implementation detail of the hash map -/
 theorem WF.size_buckets_pos [BEq α] [Hashable α] (m : Raw α β) : WF m → 0 < m.buckets.size
@@ -534,10 +522,6 @@ theorem WF.size_buckets_pos [BEq α] [Hashable α] (m : Raw α β) : WF m → 0
  | getThenInsertIfNew?₀ _ => (Raw₀.getThenInsertIfNew? ⟨_, _⟩ _ _).2.2
  | filter₀ _ => (Raw₀.filter _ ⟨_, _⟩).2
  | constGetThenInsertIfNew?₀ _ => (Raw₀.Const.getThenInsertIfNew? ⟨_, _⟩ _ _).2.2
-  | modify₀ _ => (Raw₀.modify _ _ _).2
-  | constModify₀ _ => (Raw₀.Const.modify _ _ _).2
-  | alter₀ _ => (Raw₀.alter _ _ _).2
-  | constAlter₀ _ => (Raw₀.Const.alter _ _ _).2

@[simp] theorem WF.empty [BEq α] [Hashable α] {c : Nat} : (Raw.empty c : Raw α β).WF :=
  .empty₀
--- a/src/Std/Data/HashMap/Basic.lean
+++ b/src/Std/Data/HashMap/Basic.lean
@@ -245,13 +245,21 @@ instance [BEq α] [Hashable α] {m : Type w → Type w} : ForIn m (HashMap α β
    Array β :=
  m.inner.valuesArray

-@[inline, inherit_doc DHashMap.modify] def modify (m : HashMap α β) (a : α) (f : β → β) :
-    HashMap α β :=
-  ⟨DHashMap.Const.modify m.inner a f⟩
+@[inline, inherit_doc DHashMap.modify] def modify (m : HashMap α β) (a : α) (f : β → β) : HashMap α β :=
+  match m.get? a with
+  | none => m
+  | some b => m.erase a |>.insert a (f b)

-@[inline, inherit_doc DHashMap.alter] def alter (m : HashMap α β) (a : α)
-    (f : Option β → Option β) : HashMap α β :=
-  ⟨DHashMap.Const.alter m.inner a f⟩
+@[inline, inherit_doc DHashMap.alter] def alter (m : HashMap α β) (a : α) (f : Option β → Option β) : HashMap α β :=
+  match m.get? a with
+  | none =>
+    match f none with
+    | none => m
+    | some b => m.insert a b
+  | some b =>
+    match f (some b) with
+    | none => m.erase a
+    | some b => m.erase a |>.insert a b

@[inline, inherit_doc DHashMap.Const.insertMany] def insertMany {ρ : Type w}
    [ForIn Id ρ (α × β)] (m : HashMap α β) (l : ρ) : HashMap α β :=
--- a/src/Std/Internal.lean
+++ b/src/Std/Internal.lean
@@ -4,9 +4,7 @@ Released under Apache 2.0 license as described in the file LICENSE.
 Authors: Henrik Böving
 -/
 prelude
-import Std.Internal.Async
 import Std.Internal.Parsec
-import Std.Internal.UV

 /-!
 This directory is used for components of the standard library that are either considered
--- a/src/Std/Internal/Async.lean
+++ b/src/Std/Internal/Async.lean
@@ -1,8 +0,0 @@
-/-
-Copyright (c) 2024 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Std.Internal.Async.Basic
-import Std.Internal.Async.Timer
--- a/src/Std/Internal/Async/Basic.lean
+++ b/src/Std/Internal/Async/Basic.lean
@@ -1,115 +0,0 @@
-/-
-Copyright (c) 2024 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Init.Core
-import Init.System.IO
-import Init.System.Promise
-
-namespace Std
-namespace Internal
-namespace IO
-namespace Async
-
-/--
-A `Task` that may resolve to a value or an `IO.Error`.
-/
-def AsyncTask (α : Type u) : Type u := Task (Except IO.Error α)
-
-namespace AsyncTask
-
-/--
-Construct an `AsyncTask` that is already resolved with value `x`.
-/
-@[inline]
-protected def pure (x : α) : AsyncTask α := Task.pure <| .ok x
-
-instance : Pure AsyncTask where
-  pure := AsyncTask.pure
-
-/--
-Create a new `AsyncTask` that will run after `x` has finished.
-If `x`:
- errors, return an `AsyncTask` that resolves to the error.
- succeeds, run `f` on the result of `x` and return the `AsyncTask` produced by `f`.
-/
-@[inline]
-protected def bind (x : AsyncTask α) (f : α → AsyncTask β) : AsyncTask β :=
-  Task.bind x fun r =>
-    match r with
-    | .ok a => f a
-    | .error e => Task.pure <| .error e
-
-/--
-Create a new `AsyncTask` that will run after `x` has finished.
-If `x`:
- errors, return an `AsyncTask` that reolves to the error.
- succeeds, return an `AsyncTask` that resolves to `f x`.
-/
-@[inline]
-def map (f : α → β) (x : AsyncTask α) : AsyncTask β :=
-  Task.map (x := x) fun r =>
-    match r with
-    | .ok a => .ok (f a)
-    | .error e => .error e
-
-/--
-Similar to `bind`, however `f` has access to the `IO` monad. If `f` throws an error, the returned
-`AsyncTask` resolves to that error.
-/
-@[inline]
-def bindIO (x : AsyncTask α) (f : α → IO (AsyncTask β)) : BaseIO (AsyncTask β) :=
-  IO.bindTask x fun r =>
-    match r with
-    | .ok a => f a
-    | .error e => .error e
-
-/--
-Similar to `bind`, however `f` has access to the `IO` monad. If `f` throws an error, the returned
-`AsyncTask` resolves to that error.
-/
-@[inline]
-def mapIO (f : α → IO β) (x : AsyncTask α) : BaseIO (AsyncTask β) :=
-  IO.mapTask (t := x) fun r =>
-    match r with
-    | .ok a => f a
-    | .error e => .error e
-
-/--
-Block until the `AsyncTask` in `x` finishes.
-/
-def block (x : AsyncTask α) : IO α := do
-  let res := x.get
-  match res with
-  | .ok a => return a
-  | .error e => .error e
-
-/--
-Create an `AsyncTask` that resolves to the value of `x`.
-/
-@[inline]
-def ofPromise (x : IO.Promise (Except IO.Error α)) : AsyncTask α :=
-  x.result
-
-/--
-Create an `AsyncTask` that resolves to the value of `x`.
-/
-@[inline]
-def ofPurePromise (x : IO.Promise α) : AsyncTask α :=
-  x.result.map pure
-
-/--
-Obtain the `IO.TaskState` of `x`.
-/
-@[inline]
-def getState (x : AsyncTask α) : BaseIO IO.TaskState :=
-  IO.getTaskState x
-
-end AsyncTask
-
-end Async
-end IO
-end Internal
-end Std
--- a/src/Std/Internal/Async/Timer.lean
+++ b/src/Std/Internal/Async/Timer.lean
@@ -1,139 +0,0 @@
-/-
-Copyright (c) 2024 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Std.Time
-import Std.Internal.UV
-import Std.Internal.Async.Basic
-
-
-namespace Std
-namespace Internal
-namespace IO
-namespace Async
-
-/--
-`Sleep` can be used to sleep for some duration once.
-The underlying timer has millisecond resolution.
-/
-structure Sleep where
-  private ofNative ::
-    native : Internal.UV.Timer
-
-namespace Sleep
-
-/--
-Set up a `Sleep` that waits for `duration` milliseconds.
-This function only initializes but does not yet start the timer.
-/
-@[inline]
-def mk (duration : Std.Time.Millisecond.Offset) : IO Sleep := do
-  let native ← Internal.UV.Timer.mk duration.toInt.toNat.toUInt64 false
-  return ofNative native
-
-/--
-If:
- `s` is not yet running start it and return an `AsyncTask` that will resolve once the previously
-   configured `duration` has run out.
- `s` is already or not anymore running return the same `AsyncTask` as the first call to `wait`.
-/
-@[inline]
-def wait (s : Sleep) : IO (AsyncTask Unit) := do
-  let promise ← s.native.next
-  return .ofPurePromise promise
-
-/--
-If:
- `s` is still running the timer restarts counting from now and finishes after `duration`
-  milliseconds.
- `s` is not yet or not anymore running this is a no-op.
-/
-@[inline]
-def reset (s : Sleep) : IO Unit :=
-  s.native.reset
-
-/--
-If:
- `s` is still running this stops `s` without resolving any remaining `AsyncTask`s that were created
-  through `wait`. Note that if another `AsyncTask` is binding on any of these it is going hang
-  forever without further intervention.
- `s` is not yet or not anymore running this is a no-op.
-/
-@[inline]
-def stop (s : Sleep) : IO Unit :=
-  s.native.stop
-
-end Sleep
-
-/--
-Return an `AsyncTask` that resolves after `duration`.
-/
-def sleep (duration : Std.Time.Millisecond.Offset) : IO (AsyncTask Unit) := do
-  let sleeper ← Sleep.mk duration
-  sleeper.wait
-
-/--
-`Interval` can be used to repeatedly wait for some duration like a clock.
-The underlying timer has millisecond resolution.
-/
-structure Interval where
-  private ofNative ::
-    native : Internal.UV.Timer
-
-
-namespace Interval
-
-/--
-Setup up an `Interval` that waits for `duration` milliseconds.
-This function only initializes but does not yet start the timer.
-/
-@[inline]
-def mk (duration : Std.Time.Millisecond.Offset) (_ : 0 < duration := by decide) : IO Interval := do
-  let native ← Internal.UV.Timer.mk duration.toInt.toNat.toUInt64 true
-  return ofNative native
-
-/--
-If:
- `i` is not yet running start it and return an `AsyncTask` that resolves right away as the 0th
-  multiple of `duration` has elapsed.
- `i` is already running and:
-  - the tick from the last call of `i` has not yet finished return the same `AsyncTask` as the last
-    call
-  - the tick frrom the last call of `i` has finished return a new `AsyncTask` that waits for the
-    closest next tick from the time of calling this function.
- `i` is not running aymore this is a no-op.
-/
-@[inline]
-def tick (i : Interval) : IO (AsyncTask Unit) := do
-  let promise ← i.native.next
-  return .ofPurePromise promise
-
-/--
-If:
- `Interval.tick` was called on `i` before the timer restarts counting from now and the next tick
-   happens in `duration`.
- `i` is not yet or not anymore running this is a no-op.
-/
-@[inline]
-def reset (i : Interval) : IO Unit :=
-  i.native.reset
-
-/--
-If:
- `i` is still running this stops `i` without resolving any remaing `AsyncTask` that were created
-  through `tick`. Note that if another `AsyncTask` is binding on any of these it is going hang
-  forever without further intervention.
- `i` is not yet or not anymore running this is a no-op.
-/
-@[inline]
-def stop (i : Interval) : IO Unit :=
-  i.native.stop
-
-end Interval
-
-end Async
-end IO
-end Internal
-end Std
--- a/src/Std/Internal/UV.lean
+++ b/src/Std/Internal/UV.lean
@@ -1,119 +0,0 @@
-/-
-Copyright (c) 2024 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Sofia Rodrigues
-/
-prelude
-import Init.System.IO
-import Init.System.Promise
-
-namespace Std
-namespace Internal
-namespace UV
-
-namespace Loop
-
-/--
-Options for configuring the event loop behavior.
-/
-structure Loop.Options where
-  /--
-  Accumulate the amount of idle time the event loop spends in the event provider.
-  -/
-  accumulateIdleTime : Bool := False
-
-  /--
-  Block a SIGPROF signal when polling for new events. It's commonly used for unnecessary wakeups
-  when using a sampling profiler.
-  -/
-  blockSigProfSignal : Bool := False
-
-/--
-Configures the event loop with the specified options.
-/
-@[extern "lean_uv_event_loop_configure"]
-opaque configure (options : Loop.Options) : BaseIO Unit
-
-/--
-Checks if the event loop is still active and processing events.
-/
-@[extern "lean_uv_event_loop_alive"]
-opaque alive : BaseIO Bool
-
-end Loop
-
-private opaque TimerImpl : NonemptyType.{0}
-
-/--
-`Timer`s are used to generate `IO.Promise`s that resolve after some time.
-
-A `Timer` can be in one of 3 states:
- Right after construction it's initial.
- While it is ticking it's running.
- If it has stopped for some reason it's finished.
-
-This together with whether it was set up as `repeating` with `Timer.new` determines the behavior
-of all functions on `Timer`s.
-/
-def Timer : Type := TimerImpl.type
-
-instance : Nonempty Timer := TimerImpl.property
-
-namespace Timer
-
-/--
-This creates a `Timer` in the initial state and doesn't run it yet.
- If `repeating` is `false` this constructs a timer that resolves once after `durationMs`
-  milliseconds, counting from when it's run.
- If `repeating` is `true` this constructs a timer that resolves after multiples of `durationMs`
-  milliseconds, counting from when it's run. Note that this includes the 0th multiple right after
-  starting the timer. Furthermore a repeating timer will only be freed after `Timer.stop` is called.
-/
-@[extern "lean_uv_timer_mk"]
-opaque mk (timeout : UInt64) (repeating : Bool) : IO Timer
-
-/--
-This function has different behavior depending on the state and configuration of the `Timer`:
- if `repeating` is `false` and:
-  - it is initial, run it and return a new `IO.Promise` that is set to resolve once `durationMs`
-    milliseconds have elapsed. After this `IO.Promise` is resolved the `Timer` is finished.
-  - it is running or finished, return the same `IO.Promise` that the first call to `next` returned.
- if `repeating` is `true` and:
-  - it is initial, run it and return a new `IO.Promise` that resolves right away
-    (as it is the 0th multiple of `durationMs`).
-  - it is running, check whether the last returned `IO.Promise` is already resolved:
-     - If it is, return a new `IO.Promise` that resolves upon finishing the next cycle
-     - If it is not, return the last `IO.Promise`
-     This ensures that the returned `IO.Promise` resolves at the next repetition of the timer.
-  - if it is finished, return the last `IO.Promise` created by `next`. Notably this could be one
-    that never resolves if the timer was stopped before fulfilling the last one.
-/
-@[extern "lean_uv_timer_next"]
-opaque next (timer : @& Timer) : IO (IO.Promise Unit)
-
-/--
-This function has different behavior depending on the state and configuration of the `Timer`:
- If it is initial or finished this is a no-op.
- If it is running and `repeating` is `false` this will delay the resolution of the timer until
-  `durationMs` milliseconds after the call of this function.
- Delay the resolution of the next tick of the timer until `durationMs` milliseconds after the
-  call of this function, then continue normal ticking behavior from there.
-/
-@[extern "lean_uv_timer_reset"]
-opaque reset (timer : @& Timer) : IO Unit
-
-/--
-This function has different behavior depending on the state of the `Timer`:
- If it is initial or finished this is a no-op.
- If it is running the execution of the timer is stopped and it is put into the finished state.
-  Note that if the last `IO.Promise` generated by `next` is unresolved and being waited
-  on this creates a memory leak and the waiting task is not going to be awoken anymore.
-/
-@[extern "lean_uv_timer_stop"]
-opaque stop (timer : @& Timer) : IO Unit
-
-end Timer
-
-end UV
-end Internal
-end Std
--- a/src/Std/Net.lean
+++ b/src/Std/Net.lean
@@ -1,7 +0,0 @@
-/-
-Copyright (c) 2025 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Std.Net.Addr
--- a/src/Std/Net/Addr.lean
+++ b/src/Std/Net/Addr.lean
@@ -1,197 +0,0 @@
-/-
-Copyright (c) 2025 Lean FRO, LLC. All rights reserved.
-Released under Apache 2.0 license as described in the file LICENSE.
-Authors: Henrik Böving
-/
-prelude
-import Init.Data.Vector.Basic
-
-/-!
-This module contains Lean representations of IP and socket addresses:
- `IPv4Addr`: Representing IPv4 addresses.
- `SocketAddressV4`: Representing a pair of IPv4 address and port.
- `IPv6Addr`: Representing IPv6 addresses.
- `SocketAddressV6`: Representing a pair of IPv6 address and port.
- `IPAddr`: Can either be an `IPv4Addr` or an `IPv6Addr`.
- `SocketAddress`: Can either be a `SocketAddressV4` or `SocketAddressV6`.
-/
-
-namespace Std
-namespace Net
-
-/--
-Representation of an IPv4 address.
-/
-structure IPv4Addr where
-  /--
-  This structure represents the address: `octets[0].octets[1].octets[2].octets[3]`.
-  -/
-  octets : Vector UInt8 4
-  deriving Inhabited, DecidableEq
-
-/--
-A pair of an `IPv4Addr` and a port.
-/
-structure SocketAddressV4 where
-  addr : IPv4Addr
-  port : UInt16
-  deriving Inhabited, DecidableEq
-
-/--
-Representation of an IPv6 address.
-/
-structure IPv6Addr where
-  /--
-  This structure represents the address: `segments[0]:segments[1]:...`.
-  -/
-  segments : Vector UInt16 8
-  deriving Inhabited, DecidableEq
-
-/--
-A pair of an `IPv6Addr` and a port.
-/
-structure SocketAddressV6 where
-  addr : IPv6Addr
-  port : UInt16
-  deriving Inhabited, DecidableEq
-
-/--
-An IP address, either IPv4 or IPv6.
-/
-inductive IPAddr where
-  | v4 (addr : IPv4Addr)
-  | v6 (addr : IPv6Addr)
-  deriving Inhabited, DecidableEq
-
-/--
-Either a `SocketAddressV4` or `SocketAddressV6`.
-/
-inductive SocketAddress where
-  | v4 (addr : SocketAddressV4)
-  | v6 (addr : SocketAddressV6)
-  deriving Inhabited, DecidableEq
-
-/--
-The kinds of address families supported by Lean, currently only IP variants.
-/
-inductive AddressFamily where
-  | ipv4
-  | ipv6
-  deriving Inhabited, DecidableEq
-
-namespace IPv4Addr
-
-/--
-Build the IPv4 address `a.b.c.d`.
-/
-def ofParts (a b c d : UInt8) : IPv4Addr :=
-  { octets := #v[a, b, c, d] }
-
-/--
-Try to parse `s` as an IPv4 address, returning `none` on failure.
-/
-@[extern "lean_uv_pton_v4"]
-opaque ofString (s : @&String) : Option IPv4Addr
-
-/--
-Turn `addr` into a `String` in the usual IPv4 format.
-/
-@[extern "lean_uv_ntop_v4"]
-opaque toString (addr : @&IPv4Addr) : String
-
-instance : ToString IPv4Addr where
-  toString := toString
-
-instance : Coe IPv4Addr IPAddr where
-  coe addr := .v4 addr
-
-end IPv4Addr
-
-namespace SocketAddressV4
-
-instance : Coe SocketAddressV4 SocketAddress where
-  coe addr := .v4 addr
-
-end SocketAddressV4
-
-namespace IPv6Addr
-
-/--
-Build the IPv6 address `a:b:c:d:e:f:g:h`.
-/
-def ofParts (a b c d e f g h : UInt16) : IPv6Addr :=
-  { segments := #v[a, b, c, d, e, f, g, h] }
-
-/--
-Try to parse `s` as an IPv6 address according to
-[RFC 2373](https://datatracker.ietf.org/doc/html/rfc2373), returning `none` on failure.
-/
-@[extern "lean_uv_pton_v6"]
-opaque ofString (s : @&String) : Option IPv6Addr
-
-/--
-Turn `addr` into a `String` in the IPv6 format described in
-[RFC 2373](https://datatracker.ietf.org/doc/html/rfc2373).
-/
-@[extern "lean_uv_ntop_v6"]
-opaque toString (addr : @&IPv6Addr) : String
-
-instance : ToString IPv6Addr where
-  toString := toString
-
-instance : Coe IPv6Addr IPAddr where
-  coe addr := .v6 addr
-
-end IPv6Addr
-
-namespace SocketAddressV6
-
-instance : Coe SocketAddressV6 SocketAddress where
-  coe addr := .v6 addr
-
-end SocketAddressV6
-
-namespace IPAddr
-
-/--
-Obtain the `AddressFamily` associated with an `IPAddr`.
-/
-def family : IPAddr → AddressFamily
-  | .v4 .. => .ipv4
-  | .v6 .. => .ipv6
-
-def toString : IPAddr → String
-  | .v4 addr => addr.toString
-  | .v6 addr => addr.toString
-
-instance : ToString IPAddr where
-  toString := toString
-
-end IPAddr
-
-namespace SocketAddress
-
-/--
-Obtain the `AddressFamily` associated with a `SocketAddress`.
-/
-def family : SocketAddress → AddressFamily
-  | .v4 .. => .ipv4
-  | .v6 .. => .ipv6
-
-/--
-Obtain the `IPAddr` contained in a `SocketAddress`.
-/
-def ipAddr : SocketAddress → IPAddr
-  | .v4 sa  => .v4 sa.addr
-  | .v6 sa  => .v6 sa.addr
-
-/--
-Obtain the port contained in a `SocketAddress`.
-/
-def port : SocketAddress → UInt16
-  | .v4 sa | .v6 sa => sa.port
-
-end SocketAddress
-
-end Net
-end Std
--- a/Show More
+++ b/Show More
Author	SHA1	Message	Date
Leonardo de Moura	7d842dce23	feat: add `propagateForallPropDown`	2025-01-08 09:40:35 -08:00
Leonardo de Moura	3f1cd54278	fix: bug in `propagateImpliesDown`	2025-01-08 09:18:14 -08:00
Kim Morrison	0a7bdeaf59	term has not been internalized	2025-01-08 08:23:56 -08:00