Last updated: May 11, 2026
Rafter Length Calculator
The rafter length is one of the most critical measurements in residential and commercial roof framing. It determines how much lumber to cut, how the roof slope is expressed structurally, and how load travels from the ridge board down to the wall plate. A building with a horizontal run of 12 feet and a 6/12 roof pitch has a common rafter length of approximately 13.42 feet — meaning each rafter must be cut precisely to that dimension for the framing to close correctly at the ridge.
In the Pythagorean triangle of roof framing, the horizontal run forms the base, the vertical rise forms the height, and the rafter length forms the hypotenuse. Every measurement downstream — from sheathing area to lumber count to material cost — depends on this single number being correct. A framer working with a 4/12 pitch on a 14-foot run and a framer handling a 10/12 pitch on the same run will cut rafters of completely different lengths, and both will be exactly right for their project.
Use this free Rafter Length Calculator to compute common rafter length, ridge board height, roof area, lumber requirements, and project cost — instantly and without registration.
What Is a Rafter?
Rafter Definition
A rafter is a structural framing member that runs from the ridge board at the peak of a roof down to the wall plate at the top of the exterior wall. It forms the sloped surface of the roof and provides the structural skeleton onto which roof sheathing, underlayment, and finish roofing materials are attached.
A rafter is a sloped structural member that spans from the roof ridge to the wall plate, forming the inclined surface of a pitched roof. Its length is determined by the horizontal run and the roof pitch, calculated using the Pythagorean theorem.
Types of Rafters in Roof Framing
Roof framing uses several types of rafters, each serving a distinct structural role:
| Rafter Type | Description | Where Used |
| Common Rafter | Runs perpendicular from ridge to wall plate at uniform spacing | All gable, hip, and shed roofs |
| Hip Rafter | Runs diagonally from the corner of the wall plate to the ridge end | Hip roofs at each corner |
| Valley Rafter | Runs diagonally along the intersection of two roof slopes | Where two roof planes meet |
| Jack Rafter | Shorter rafter that connects to a hip or valley rafter, not the ridge | Hip and valley framing |
| Ridge Rafter | Horizontal beam at the peak to which common rafters attach | All pitched roofs |
| Barge Rafter | Outer rafter at the gable end, often decorative and non-load-bearing | Gable overhangs |
Use our roof pitch calculator to calculate roof slope, rise, angle, and pitch ratio with accurate results. It’s ideal for roof framing, construction planning, and roofing projects.
What Does a Rafter Length of 13.42 Feet Actually Mean?
A rafter length of 13.42 feet means the framing member must be cut to that dimension measured along the slope — from the plumb cut at the ridge to the seat cut (bird’s mouth) at the wall plate, before adding any tail for the overhang. In practical terms:
- A carpenter measures 13.42 feet along the rafter stock from the ridge cut mark
- The bird’s mouth notch is cut at that point to seat the rafter on the wall plate
- Any additional tail length for soffit overhang is added beyond the bird’s mouth
- Both sides of a symmetric gable roof require identical rafter cuts
Why Rafter Length Is Important
For Framers — Precision Cuts Prevent Rework
Every rafter on a residential roof must be cut to the same length within a very tight tolerance. If rafters vary by even half an inch, the ridge will not sit level, the wall plates will be stressed unevenly, and the sheathing will not lie flat. Professional framers calculate rafter length before touching a saw, and they verify the number against field measurements before cutting an entire bundle.
- Controls ridge board height and horizontal alignment
- Ensures uniform rafter tail length for consistent fascia and soffit lines
- Prevents waste from over-cut lumber that cannot be reused
- Enables pre-cutting all rafters on the ground before raising the frame
For Estimators — Accurate Material Takeoffs
Rafter length drives the entire materials estimate for a roofing project. Lumber count, sheathing square footage, underlayment rolls, and roofing material quantities all depend on knowing the actual rafter length — not the horizontal run. A 12-foot run does not mean 12-foot rafters; the actual sloped length is always longer, and every pitch produces a different multiplier.
- Determines how many board feet of lumber to order
- Drives sheathing area calculations for OSB or plywood
- Informs roofing material takeoffs for shingles, metal panels, or tiles
- Enables accurate labor hour estimates per rafter installed
For Homeowners — Understanding Your Roof Framing Quote
A homeowner reviewing a contractor’s bid for a new roof or addition needs to understand how rafter length affects cost. A steeper pitch means longer rafters, more lumber, more sheathing, and more labor per square foot of floor area. Understanding the relationship between run, pitch, and rafter length helps homeowners evaluate bids and ask informed questions.
Use our floor joist calculator to estimate joist span, spacing, load capacity, and framing requirements with accurate results. It’s ideal for floor framing, structural engineering, and residential construction projects.
The Rafter Length Formula
The Standard Rafter Length Formula
| Rafter Length = √(Run² + Rise²) |
This is the Pythagorean theorem applied to the right triangle formed by a pitched roof. The horizontal run is the base of the triangle, the vertical rise is the height, and the rafter length is the hypotenuse.
How to Calculate Rise from Pitch
Roof pitch is expressed as a ratio of rise to run, always measured over 12 inches. A 6/12 pitch rises 6 inches for every 12 inches of horizontal run.
| Formula | Example |
| Rise = Run × (Pitch ÷ 12) | Run = 12 ft, Pitch = 6/12 → Rise = 12 × (6 ÷ 12) = 6 ft |
| Rafter = √(Run² + Rise²) | √(12² + 6²) = √(144 + 36) = √180 = 13.42 ft |
| Pitch Multiplier = √(1 + (Pitch/12)²) | 6/12 pitch → √(1 + 0.25) = √1.25 = 1.118 |
The Pitch Multiplier Shortcut
Experienced framers use a pitch multiplier — a single number that converts horizontal run to rafter length with one multiplication. This multiplier is derived from the Pythagorean formula and is constant for any given pitch:
| Roof Pitch | Rise Angle | Pitch Multiplier | Rafter for 12 ft Run |
| 2/12 | 9.5° | ×1.0138 | 12.17 ft |
| 3/12 | 14.0° | ×1.0308 | 12.37 ft |
| 4/12 | 18.4° | ×1.0541 | 12.65 ft |
| 5/12 | 22.6° | ×1.0833 | 13.00 ft |
| 6/12 | 26.6° | ×1.1180 | 13.42 ft |
| 7/12 | 30.3° | ×1.1577 | 13.89 ft |
| 8/12 | 33.7° | ×1.2019 | 14.42 ft |
| 9/12 | 36.9° | ×1.2500 | 15.00 ft |
| 10/12 | 39.8° | ×1.3017 | 15.62 ft |
| 12/12 | 45.0° | ×1.4142 | 16.97 ft |
Step-by-Step Rafter Length Calculation
- Measure or calculate the horizontal run (half the building span for a symmetric gable roof)
- Determine the roof pitch in X/12 notation (e.g., 6/12 means 6-inch rise per 12-inch run)
- Calculate the vertical rise: Rise = Run × (Pitch ÷ 12)
- Apply the Pythagorean formula: Rafter = √(Run² + Rise²)
- Add any overhang tail length beyond the bird’s mouth if needed
- Add a cutting allowance (typically 1–2 inches) for the plumb cut at the ridge
Rafter Length Example Calculation
Example Project — Gable Addition
Consider a residential addition with the following parameters:
| Parameter | Value |
| Building span (total width) | 24 feet |
| Horizontal run (half span) | 12 feet |
| Roof pitch | 6/12 |
| Ridge board width | 1.5 inches (2x lumber) |
Step-by-Step Calculation
| Step | Formula | Result |
| Calculate run | Span ÷ 2 = 24 ÷ 2 | 12.00 ft |
| Calculate rise | Run × (Pitch ÷ 12) = 12 × 0.5 | 6.00 ft |
| Calculate rafter length | √(12² + 6²) = √180 | 13.42 ft |
| Ridge board adjustment | Subtract ½ ridge width: − (0.75 ÷ 12) × multiplier | ≈ −0.07 ft |
| Final rafter length (to ridge) | 13.42 − 0.07 | 13.35 ft |
| Add overhang tail (12 in) | 12 in × 1.118 = 13.4 in along slope | +1.12 ft |
| Total cut length per rafter | 13.35 + 1.12 | ≈ 14.47 ft |
Roof Area and Lumber Count
For a building 40 feet long with the above parameters:
| Metric | Calculation | Result |
| Roof area (one side) | Rafter length × building length = 13.42 × 40 | 536.8 sq ft |
| Total roof area (both sides) | 536.8 × 2 | 1,073.6 sq ft |
| Rafters at 16″ o.c. | (Building length ÷ 1.333) + 1 = (40 ÷ 1.333) + 1 | 31 rafters/side |
| Total rafters (both sides) | 31 × 2 | 62 rafters |
| Lumber required (14 ft stock) | 62 rafters ÷ 1 per board + 10% waste | ≈ 69 boards |
How to Use the Rafter Length Calculator
Basic Rafter Length — Step by Step
- Enter the horizontal run in feet. For a symmetric gable roof, this is half the total building span. For a shed roof, this is the full horizontal distance from wall to wall.
- Select the roof pitch from the dropdown. Common residential pitches range from 4/12 (standard) to 8/12 (steep). The calculator displays the corresponding angle.
- Click Calculate to receive the rafter length expressed in decimal feet and in feet-inches format for direct field measurement.
- Review the pitch multiplier and vertical rise displayed alongside the primary result.
Advanced Features in This Calculator
The Professional Edition includes eleven calculation modules:
| Module | What It Calculates |
| Basic Rafter Length | Common rafter from run and pitch using Pythagorean formula |
| Rise from Pitch | Vertical rise and roof angle for any run and pitch combination |
| Roof Area Calculator | Total sloped roof area for sheathing and material estimates |
| Hip/Valley Rafter Length | Diagonal rafter length for hip and valley roof geometries |
| Jack Rafter Set | Full set of jack rafter lengths spaced at 16″ or 24″ o.c. |
| Ridge Board Length | Ridge board length adjusted for overhang and building dimensions |
| Bird’s Mouth Calculator | Seat cut depth and width for proper wall plate bearing |
| Overhang Calculator | Horizontal and sloped overhang dimensions with fascia height |
| Rafter Span Tables | Maximum allowable spans by lumber size, spacing, and load |
| Pitch Comparison | Side-by-side comparison of rafter lengths across four pitches |
| Lumber Cost Estimator | Board count, board feet, and total material cost with waste factor |
Roof Pitch Guide — What Is a Good Pitch?
Pitch Classification by Slope
Roof pitch selection affects structural performance, aesthetics, drainage, and construction cost. The industry classifies pitches into four categories:
| Category | Pitch Range | Angle Range | Typical Application |
| Flat / Low Slope | 1/12 – 3/12 | 4.8° – 14.0° | Commercial roofs, additions, covered patios |
| Standard | 4/12 – 6/12 | 18.4° – 26.6° | Most residential homes, cost-effective framing |
| Steep | 7/12 – 9/12 | 30.3° – 36.9° | Traditional residential, good attic space |
| Very Steep | 10/12 – 12/12+ | 39.8° – 45°+ | Steep colonial, Victorian, decorative dormers |
How Pitch Affects Rafter Length
As pitch increases, the pitch multiplier increases, which means longer rafters for the same horizontal run. This table shows how dramatically pitch affects material requirements for a 12-foot run:
- A 2/12 pitch produces a 12.17 ft rafter — only 1.4% longer than the run
- A 6/12 pitch produces a 13.42 ft rafter — 11.8% longer than the run
- A 12/12 pitch produces a 16.97 ft rafter — 41.4% longer than the run
Every inch of run lost to a steeper pitch means longer rafters, more lumber, more sheathing, and more roofing material. A steep roof on a large building can require 40% more structural lumber than the same building framed at a standard pitch.
Drainage and Climate Considerations
Roof pitch selection is also driven by climate and drainage requirements. Regions with heavy snow loads typically require steeper pitches to shed snow before it accumulates. Tropical regions with intense rainfall benefit from steeper slopes that drain quickly. Arid regions often use flatter pitches for aesthetic and cost reasons, relying on roofing materials rated for low-slope applications.
| Climate Factor | Recommended Minimum Pitch | Reason |
| Heavy snow regions | 6/12 or steeper | Snow load shedding; prevents ice dam formation |
| High rainfall regions | 4/12 or steeper | Rapid water runoff; reduces leak risk |
| High wind regions | 4/12 – 6/12 | Lower profile reduces wind uplift forces |
| Arid/desert regions | 2/12 – 4/12 acceptable | Minimal drainage demand; material savings |
Hip Rafter and Valley Rafter Length
What Is a Hip Rafter?
A hip rafter runs diagonally from each corner of the building to the end of the ridge board. Because it travels diagonally in plan, it must span a greater horizontal distance than a common rafter — the diagonal of the run square rather than the run itself. This requires a different length calculation.
| Hip Rafter Length Formula |
| Hip Rafter = √((Run × √2)² + Rise²) — or equivalently — Hip Rafter = √(2 × Run² + Rise²) |
Hip Rafter Example
For the same 12-foot run and 6/12 pitch used in the common rafter example:
| Component | Calculation | Result |
| Diagonal run | 12 × √2 | 16.97 ft |
| Rise | 12 × (6 ÷ 12) | 6.00 ft |
| Hip rafter length | √(16.97² + 6²) = √(287.98 + 36) | √323.98 = 18.00 ft |
Valley Rafter Length
A valley rafter runs along the internal angle where two roof planes intersect, forming a V-shaped valley. Its geometry is identical to the hip rafter because both travel the same diagonal distance in plan. The valley rafter formula is therefore the same as the hip rafter formula:
| Valley Rafter Length Formula |
| Valley Rafter = √(2 × Run² + Rise²) |
Jack Rafter Length
What Is a Jack Rafter?
Jack rafters are shortened common rafters that connect either to a hip rafter (hip jacks) or to a valley rafter (valley jacks) instead of running to the ridge. Each jack in a set is shorter than the previous by a constant difference called the common difference.
Common Difference Formula for Jack Rafters
| Formula |
| Common Difference = Rafter Spacing × Pitch Multiplier |
| For 16″ o.c. spacing and 6/12 pitch: CD = (16/12) × 1.118 = 1.49 ft = 1’−5⅞” |
| For 24″ o.c. spacing and 6/12 pitch: CD = (24/12) × 1.118 = 2.24 ft = 2’−2⅞” |
Jack Rafter Set for 6/12 Pitch at 16″ o.c.
Starting from the full-length hip jack (equal to the common rafter length) and subtracting the common difference:
| Jack Number | Length (decimal ft) | Length (ft-in) | Location |
| 1 (longest) | 13.42 ft | 13’−5″ | Adjacent to corner |
| 2 | 11.93 ft | 11’−11″ | Second from corner |
| 3 | 10.44 ft | 10’−5¼” | Third from corner |
| 4 | 8.95 ft | 8’−11⅜” | Fourth from corner |
| 5 | 7.46 ft | 7’−5½” | Fifth from corner |
| 6 (shortest) | 5.97 ft | 5’−11⅝” | Nearest ridge end |
Bird’s Mouth Cut
What Is a Bird’s Mouth?
The bird’s mouth is a notch cut into the underside of each common rafter at the point where it bears on the top of the wall plate. It consists of two cuts: a plumb cut (vertical, parallel to the building walls) and a seat cut (horizontal, resting on the wall plate). A proper bird’s mouth transfers roof loads from the rafter into the wall framing.
Bird’s Mouth Dimensions
| Dimension | Rule of Thumb | Notes |
| Seat cut depth | Maximum 1/3 of rafter depth | Deeper cuts weaken the rafter at its bearing point |
| Seat cut width | Equal to top plate width (3.5″ for 2×4; 5.5″ for 2×6) | Must bear fully on plate for load transfer |
| Plumb cut height | Determined by seat cut depth and pitch angle | Must be plumb (vertical) to match wall |
| HAP (Height at Plate) | Distance from seat cut to top of rafter | Controls ceiling height and ridge board elevation |
Rafter Span Tables — Maximum Allowable Spans
How Rafter Span Tables Work
Building codes establish maximum allowable rafter spans based on lumber species, grade, size, spacing, and roof load. The span is measured horizontally from the outside face of the supporting wall to the center of the ridge board. Exceeding the allowable span requires a larger lumber size, closer spacing, or a structural ridge beam.
Use our beam deflection calculator to calculate beam bending, slope, and deflection under different loads with accurate results. It’s ideal for structural engineering, construction, and framing design projects.
Allowable Spans for Southern Pine — 30 PSF Live Load, 10 PSF Dead Load
| Lumber Size | Spacing 12″ o.c. | Spacing 16″ o.c. | Spacing 24″ o.c. |
| 2×6 | 14’−6″ | 13’−2″ | 11’−6″ |
| 2×8 | 19’−1″ | 17’−4″ | 15’−2″ |
| 2×10 | 24’−5″ | 22’−2″ | 19’−4″ |
| 2×12 | 29’−8″ | 26’−11″ | 23’−7″ |
Note: These values are representative for select structural-grade Southern Pine. Always verify with your local building code and a licensed structural engineer for permit-required projects.
Roof Area Calculation
Sloped vs. Horizontal Roof Area
The horizontal projection of a roof (footprint) is not the same as the actual sloped surface area. Because rafters travel along the slope, the surface they cover is always larger than the floor area below. The ratio between sloped area and horizontal area is the pitch multiplier.
| Area Type | Formula | When to Use |
| Horizontal (plan) area | Building length × Building width | Attic floor area, drainage basin calculations |
| Sloped roof area | Horizontal area × Pitch multiplier | Sheathing, underlayment, roofing materials |
| Sloped area — single slope | Rafter length × Building length | Shed roofs, single-plane calculations |
| Sloped area — gable roof | (Rafter length × Building length) × 2 | Full gable roofs, both sides |
Roof Area Example — 40 × 24 Building at 6/12 Pitch
| Step | Calculation | Result |
| Horizontal plan area | 40 ft × 24 ft | 960 sq ft |
| Pitch multiplier for 6/12 | √(1 + 0.25) = √1.25 | 1.118 |
| Total sloped area | 960 × 1.118 | 1,073 sq ft |
| Add 10% waste/overlap | 1,073 × 1.10 | 1,180 sq ft ordered |
| Convert to squares | 1,180 ÷ 100 | 11.8 squares |
Use our square footage calculator to measure room area, roof area, flooring dimensions, and building size with accurate results. It’s ideal for construction, renovation, and material estimation projects.
Ridge Board Length
Ridge Board Length Formula
The ridge board runs horizontally at the peak of the roof and must be long enough to span the full building length plus any overhang extensions. For a simple gable roof, the ridge board length equals the building length. For hip roofs, the ridge length is shorter — it is reduced by the run dimension on each end where the hip rafters begin.
| Roof Type | Ridge Board Length Formula |
| Gable roof | Building length + (2 × overhang extension) |
| Hip roof | Building length − (2 × run) + (2 × overhang extension) |
| Shed roof | No ridge board — single slope bears on front and back walls |
Lumber Estimation and Cost
Calculating Rafter Lumber Requirements
Accurate lumber estimation prevents both costly material shortages and wasteful overbuying. The key variables are rafter length, rafter count, stock lumber length, and a waste factor to account for defects, cutting waste, and layout errors.
| Step | Formula | Example (28 rafters, 14.5 ft each) |
| Rafters per 16-ft board | Floor(16 ÷ rafter length) | Floor(16 ÷ 14.5) = 1 rafter/board |
| Boards needed (net) | Ceiling(rafter count ÷ rafters per board) | Ceiling(28 ÷ 1) = 28 boards |
| Add 10% waste factor | Net boards × 1.10 | 28 × 1.10 = 31 boards |
| Board feet per 2×8×16 | (1.5 × 7.25 × 16) ÷ 12 | 14.5 BF per board |
| Total board feet | 31 × 14.5 | 449.5 BF |
| Cost at $2.80/BF | 449.5 × $2.80 | $1,259 material cost |
Common Lumber Sizes for Rafters
| Nominal Size | Actual Size | Board Feet per 12 ft | Typical Use |
| 2×6 | 1.5″ × 5.5″ | 5.5 BF | Short spans, low-slope roofs up to 14 ft |
| 2×8 | 1.5″ × 7.25″ | 7.25 BF | Standard residential spans 14–18 ft |
| 2×10 | 1.5″ × 9.25″ | 9.25 BF | Longer spans, steeper loads, snow country |
| 2×12 | 1.5″ × 11.25″ | 11.25 BF | Maximum span residential, heavy loads |
Common Mistakes to Avoid
Mistake 1 — Using the Span Instead of the Run
The most common error in rafter calculation is using the full building span instead of the run. For a symmetric gable roof, the run is always half the span. Using the full 24-foot span when the run is 12 feet will produce a rafter length nearly twice as long as needed, resulting in severely over-ordered lumber and mis-cut rafters.
Mistake 2 — Ignoring the Ridge Board Thickness
Each rafter’s plumb cut at the ridge must account for half the ridge board thickness. A standard 2× ridge board is 1.5 inches thick, so each rafter must be shortened by 0.75 inches measured horizontally (or the equivalent sloped distance). Ignoring this produces rafters that are too long and cannot meet at the ridge.
Mistake 3 — Calculating Area Before Knowing the True Slope Length
Contractors ordering sheathing or roofing material based on the floor footprint alone consistently under-order because they have not applied the pitch multiplier. A 6/12 pitch roof requires 11.8% more material than the footprint suggests; a 12/12 pitch roof requires 41.4% more. Always multiply horizontal area by the pitch multiplier to get true sloped area.
Mistake 4 — Forgetting the Tail Length
The calculated rafter length — run to ridge — does not include the overhang tail. If the design calls for a 12-inch horizontal overhang, the tail adds 1.118 feet (for a 6/12 pitch) of sloped length beyond the wall plate. Always add the tail to the calculated rafter length before ordering or cutting lumber.
Mistake 5 — Not Adding a Waste Factor to Lumber Orders
Even a perfectly calculated rafter count should include a 10–15% waste factor for cutting waste, defects in lumber, and layout errors at corners and hips. Ordering exactly the calculated quantity almost always results in a short call to the lumber yard mid-project.
Real-World Applications
New Residential Construction
General contractors use rafter length calculations at the estimating stage to develop preliminary material budgets, and framers verify the number in the field before cutting. On a standard 2,000-square-foot home with a 6/12 gable roof, precise rafter length calculations can mean the difference between an accurate lumber order and a $1,500 surplus or shortage.
Room Additions
Room additions require matching the existing roof pitch and determining rafter length for the new framing without compromising the existing structure. The rafter length calculator helps addition framers verify that new rafters will tie in at the correct height and that the ridge of the addition will align with the existing ridge or eave line.
Shed and Garage Roofs
Outbuildings often use simple shed or gable roofs where the homeowner or contractor handles framing directly. Shed roofs require calculating rafter length across the full horizontal span from front wall to back wall. The calculator handles this use case explicitly, and the resulting rafter length directly determines the lumber size required.
CFA and Construction Certification Prep
Rafter length calculation is a core competency tested in construction trade examinations and contractor licensing exams. Understanding the Pythagorean relationship between run, rise, and rafter length, applying pitch multipliers, and calculating hip and valley rafter lengths are all standard exam topics. This calculator supports both practical project use and conceptual review.
Frequently Asked Questions
What is the formula for rafter length?
What is the difference between run and span?
How do I calculate rafter length for a hip roof?
What is a pitch multiplier?
How much does roof pitch affect rafter length?
Do I need to subtract for the ridge board thickness?
What is a bird’s mouth cut and why does it matter?
How do I calculate the number of rafters I need?
Key Takeaway
Calculate common rafter length from run and pitch — the foundational roof framing measurement.
Half the span for gable roofs; full span for sheds
Standard 2x lumber = 1.5", LVL ridge = 3.5"
Horizontal projection beyond the wall plate
Rafter = sqrt(Run² + Rise²) + Overhang Slope LengthRise = Run × (Pitch ÷ 12). Ridge deduction = (Ridge Thickness ÷ 2) × Pitch Multiplier.
Compute hip and valley rafter lengths using the 17-inch method and full 3D diagonal formula.
Same as common rafter run — half the roof span
Number of inches of rise per 12 horizontal inches
Full width of the building perpendicular to ridge
Full length of the building parallel to ridge
Hip = sqrt(Run² + Run² + Rise²)Hip Unit = sqrt(17² + Pitch²) ÷ 12 ft/ft
Valley equals hip for equal-pitch roofs. Backing angle = atan(sin(45°) × tan(Pitch Angle)).
Generate a full jack rafter schedule with lengths and shortening amounts at every on-center spacing.
Horizontal run of the adjacent common rafter
Roof pitch in rise per 12" run
Standard rafter spacing; 16" most common
Hip jacks decrease toward corner; valley jacks increase
Calculate actual slope area, shingles, underlayment, and ridge cap needed with waste factor adjustment.
Exterior wall-to-wall width of the building
Exterior wall-to-wall length of the building
Roof pitch determines slope multiplier for area
Horizontal eave overhang on both sides
Slope Area = Plan Area × Pitch MultiplierPitch Multiplier = sqrt(1 + (Rise/12)²). 1 Square = 100 sq ft. Bundles = Squares × 3 (3-tab) or × 4 (arch.).
Determine plumb-cut depth, seat-cut width, HAP, and bird's mouth notch dimensions for wall plate bearing.
Roof pitch controls all cut angles
Evaluate rafter adequacy under live load, dead load, and snow load using simplified IRC span table logic.
Horizontal distance from ridge to bearing wall
IRC minimum: 20 psf for living space above, 10 psf for attic storage
Sheathing + shingles typically 10–20 psf; slate/tile 15–25 psf
Ground snow load from ASCE 7 / local building code; enter 0 if not applicable
Find the exact ridge board height above the top plate given span, pitch, and rafter/plate dimensions.
Full width of building from outside wall to outside wall
Roof pitch in inches of rise per 12 inches of run
Floor-to-top-plate height of the supporting wall
Calculate rafter tail length, fascia drop, soffit width, and plumb/level cut positions for eave trim.
Roof pitch; controls all tail cut angles
Horizontal projection of rafter tail beyond wall face
Compute miter and bevel saw settings for compound angle cuts on hip rafters, crown moulding, and angled fascia.
Pitch of the roof plane being cut
Plan angle between the two intersecting roof planes (90° for standard hip)
Compare up to four roof pitches side-by-side — rafter lengths, areas, and framing metrics for design decisions.
Enter one run; all pitches will be compared using this run
Calculate board feet, piece count, and total lumber cost for an entire rafter system with board sizing options.
Sloped rafter length from ridge to tail; from Card 1
Total rafter count for entire roof (both sides)
Current price per piece at your local supplier (2026 avg: $15–35 for 2×8×16)
Full reference table for all standard pitches — multipliers, angles, and IRC classification with interactive chart.
This calculator is for informational purposes only and does not constitute professional structural or construction advice. Consult a licensed contractor, structural engineer, or building official before making decisions on your roofing project.